Load bearing structure

ABSTRACT

The present invention provides a movable load bearing structure with a surface that includes antimicrobial agents capable of eliminating, preventing, retarding or minimizing the growth of microbes and also minimizing cross-contamination when the load bearing structure is being reused for cargoes that differ from a previously transported cargo, for example, different food types, such as poultry, fresh vegetables, and fresh fruit. The load bearing structure may be a dunnage platform or a container for storing and/or shipping cargo.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.15/321,179, filed Dec. 21, 2016, entitled “LOAD BEARING STRUCTURE”,which is a 371 national phase application of Patent Cooperation Treatyinternational application Ser. No. PCT/US15/37535, filed Jun. 24, 2015,entitled “ LOAD BEARING STRUCTURE”, which claims the priority andbenefit of U.S. provisional patent application Ser. No. 62/017,079,filed Jun. 25, 2014, entitled “LOAD BEARING STRUCTURE”. The contents ofall of the foregoing are hereby incorporated by reference in theirentireties.

FIELD OF THE INVENTION

This invention is in the general field of load-bearing structure and,more particularly, a load bearing structure for loading, storing and/ortransporting goods.

BACKGROUND OF THE INVENTION

A shipping pallet is a well known load-bearing, movable platform whereonarticles are placed for shipment. The pallet usually is loaded with amultiplicity of items, such as cartons or boxes. The loaded pallet ismovable with either a pallet truck or a forklift.

The adoption of International Standardized Phytosanitary Monitoring(ISPM)-15 for wood packaging material (WPM) requires kiln dry treatmentof all wood used in shipping crates and dunnage platforms (pallets). TheUnited States in cooperation with Mexico and Canada began enforcement ofthe ISPM 15 standard on Sep. 16, 2005. The North American PlantProtection Organization (NAPPO) strategy for enhanced enforcement willbe conducted in three phases. Phase 1, Sep. 16, 2005 through Jan. 31,2006, call for the implementation of an informed compliance via accountmanagers and notices posted in connection with cargo that containsnoncompliant WPM. Phase 2, Feb. 1, 2006 through Jul. 4, 2006, calls forrejection of violative crates and pallets through re-exportation fromNorth America. Informed compliance via account managers and noticesposted in cargo with other types of non-compliant WPM continues toremain enforce. Phase 3, Jul. 5, 2006, involves full enforcement on allarticles of regulated WPM entering North America. Non-compliantregulated WPM will not be allowed to enter the United States. Theadoption of ISPM-15 reflects the growing concern among nations aboutwood shipping products enabling the importation of wood-boring insects,including the Asian Long horned Beetle, the Asian Cerambycid Beetle, thePine Wood Nematode, the Pine Wilt Nematode and the AnoplophoraGlapripwnnis.

Thus the wooden dunnage platform has become unattractive for theinternational shipment of products. Further, the wooden surface is notsanitary since it potentially can harbor in addition to insects, mouldand bacteria. Thus, the wooden crate is generally ill-suited for theshipment of foodstuffs and other produce requiring sanitary conditions.In addition, with the concern for carbon emission, lighter weightplatforms and containers are more desirable.

Plastic dunnage platforms or pallets are known, see U.S. Pat. No.3,915,089 to Nania, and U.S. Pat. No. 6,216,608 to Woods et al., whichare herein incorporated by reference in their entirety. Thermoplasticmolded dunnage platforms are known, see for example U.S. Pat. Nos.6,786,992, 7,128,797, 7,927,677, 7,611,596, 7,923,087, 8,142,589,8,163,363 and 7,544,262, to Dummett, which is herein incorporated byreference in its entirety, discloses applying thermoplastic sheets to apreformed rigid structure for manufacturing dunnage platforms.

While the plastic surface of the plastic pallet obviates some of thesanitary problems encountered with wood pallets, because of the requiredrepetitive use, the surface can become unsanitary. Thus, when used forthe shipment of foodstuffs, drugs, pharmaceuticals, electronic parts andother products requiring sanitary conditions, the plastic pallet mayrequire that the plastic surface be cleaned and kept clean prior to use.Also, for most pallets, any bonding imperfections, either between thethermoplastic cover and the core, or the thermoplastic cover andthermoplastic cover, may lead to places where moisture, dirt, left overproducts, and microbes that thrive on either moisture, dirt or left overproducts may hide, grow and/or accumulate. These areas are usuallyhidden and are also more difficult to dry or clean than exposedsurfaces.

SUMMARY OF THE INVENTION

The present invention relates to a load bearing structure having a topside and a bottom side with a width having a thickness therebetweenjoining the top side and the bottom side. The load bearing structure mayor may not include a plurality of supports, and if present, they extendfrom the bottom side of the load bearing structure. The load bearingstructure may be constructed of a light weight polymeric core covered byor combined with one or more polymeric sheets or film with the edges ofthe sheets being adhered to either the polymeric core or to anotherpolymeric sheet by a sealing feature including those formed, forexample, using a sealing liquid, a chemical sealing composition, asealing tape or by mechanical and/or heat sealing, which may include,for example, by ultrasonic sealing device. The sealing by the sealingfeature is at the, for example, peripheral of the outer edges of thepolymeric sheet or sheets. For example, about 4 millimeters to about 12millimeters from the edge, more for example, about 5 millimeters toabout 10 millimeters from the edge, and more for example, about 5millimeters to about 8 millimeters from the edge, of a polymeric sheetis sealed with the sealing feature. The rest of the bonded area of thepolymeric sheet including the outer edges is substantially bonded withheat and/or pressure in the manufacturing process of the load bearingstructure.

The shape of the core determines the shape of the load bearingstructure. The core may include a top side and a bottom side with awidth having a thickness therebetween joining the top and bottom side,and in some instances, may or may not include a plurality of extensionsextending from the bottom side of the core. If the plurality ofextensions are present, they form the supports of the load bearingstructure. The bottom side and the extensions, if present, may becovered or combined with a polymeric sheet or film, with the sheet orfilm extending to envelope the bottom side, the extensions, if present,and either the entire thickness of the width and at least a portion ofthe top, if only one polymeric sheet or film is used, or one sheet orfilm may extend to cover one side and at least a portion of thethickness of the width while the second sheet or film may cover the restof the exposed surfaces, if two polymeric sheets or film are used tocover the top side, the entire thickness of the width, and the bottomside and may include some overlap of the sheets about the width. Thepolymeric sheet or sheets are bonded to the core to a substantial extentor if one polymeric sheet is used, substantially almost all of the sheetis bonded to the core. The bonding may be achieved by heat and/orpressure.

When the core is covered by one polymeric sheet, the sheet covers thebottom, the entire thickness of the width and at least a portion of thetop side, the outer edge portions of the polymeric sheet on the top sideof the core may be firmly sealed to a portion of the top surface of thecore by use of a sealing tape, a sealing chemical composition, a sealingliquid, or a mechanical and/or heat seal, and may include, for example,an ultrasonic sealing device. The sealing tape, sealing liquid, sealingchemical composition, or mechanical and/or heat sealing device may beused to aid in sealing the edge portion to the top side of the core,though it may also aid in sealing, but not necessarily, the rest of thesheet to the bottom of the core, the extensions if present, the entirethickness of the width and part of the top surface of the core.

When the core is covered by two polymeric sheets, the bottom sheetcovers the bottom side of the core, the extensions if present, and atleast a portion of the thickness of the width of the core, while the topsheet covers the top side of the core, and at least a portion of thethickness of the width, creating a small overlapping of the bottom sheetand the top sheet about the width of the core, if desired. At least aportion of the overlap portions of the first sheet and the second sheet,for example, at least a portion of the overlapping portions near theedges of the sheet or sheets, may be firmly sealed together by a sealingfeature, for example, by the use of a sealing tape, a sealing solvent, asealing chemical composition or a mechanical and/or heat seal, and mayinclude, for example, an ultrasonic sealing device. The sealing tape,sealing liquid, a sealing chemical composition or a mechanical and/orheat seal, and may include, for example, with an ultrasonic sealingdevice, is used for aiding in sealing the edges of the overlappingportions of the first and second sheet, and may also aid in sealing,though not necessarily, the rest of the first and second sheets to thecore and to each other.

The edges of the sheet or film may be the outer edges of the sheet orfilm, or a folded edge when some edge folding is present.

The polymeric sheet or film may be made from any film forming materialthat may impart strength to the core material, for example, anythermoplastic material including but not limited to high impactpolystyrene; polyolefins such as polypropylene, low densitypolyethylene, high density polyethylene, polyethylene, polybutylene;polycarbonate; acrylonitrile butadiene styrene; polyacrylonitrile;polyphenylene ether; polyphony ether alloyed with high impactpolystyrene (HIPS); polyester such as PET (polyethylene terephthalate),APET, and PETG; lead free PVC; copolymer polyester/polycarbonate;copolymers of any of the above mentioned polymers; or a composite HIPSstructure.

In general, the edges of the load bearing structure may include apolymeric core covered by a polymeric sheet or film, as described above.In some embodiments, additional features may be present intermittentlyor continuously around some of the edges. The features may include edgeprotectors, as described below. The edge protectors may be present onthe core or on the polymeric sheet. When present on the core, thepolymeric sheet or sheets may or may not be combined or bonded to theedge protectors. If the edge protectors are not combined or bonded tothe polymeric sheet or sheets, the outer edges of the sheet may bebonded to the edge protector by the sealing feature. the edge protectorsare combined or bonded to the polymeric sheet or sheets, the outer edgesof the sheet may also be bonded to the edge protector by the sealingfeature.

In these embodiments, the load bearing structure may be reinforced withsome edge protectors. These may be desired when cargo loaded on thestructure may be held down with cargo-holding items, for example, usingstraps, tiedowns, cables, ropes and/or other items to aid in holding thecargo in place to minimize movement, particularly during transport. Thebottom edge and portion of the width close to the bottom edge of theload bearing structure generally bear substantially the full force ofthe, for example, straps, when used. In one embodiment, the protectorsmay be present intermittently at predetermined position on the loadbearing structure where reinforcement may be needed. Straps may be usedat these same predetermined locations to help keep the cargo in place tominimize movement. In another embodiment, the edge protectors may bepresent continuously around the edges of the structure. In a furtherembodiment, protectors may be present both at the bottom and upperedges, either continuously or intermittently. According to oneembodiment, the edge protectors may have an L-shaped cross-section andmay be present either intermittently or continuously around at least aportion of the bottom and portions of the width of the core in a fashionthat they envelope a portion of the bottom side near the outer edge towrap around the edge and extending to cover a portion of the width closeto the bottom side. According to another embodiment, the edge protectorsmay have a substantially C-shaped cross-section with square edges andmay be present either intermittently or continuously around a portion ofthe bottom, width and top of the core in a fashion that they envelope aportion of the bottom side near the outer edge to wrap around the edgeand extending to cover the width and a portion of the top side close tothe width. According to a further embodiment, the edge protectors comesin pairs each having a substantially L-shaped cross-section, and may bepresent either intermittently or continuously around a portion of thebottom, width and top of the core in a fashion that one of the pairenvelopes a portion of the bottom side near the outer edge to wraparound a portion of the edge and at least a portion of the width closeto the bottom side; and the other of the pair extending to cover aportion of the width near the top side and a portion of the top sideclose to the width.

In one embodiment, the edge protector may be present on the core priorto the covering of the core by the polymeric sheet. In one aspect, thecore may be indented to accommodate the one or more protectors so thatthe one or more protectors are flushed with the rest of the core so thatthe sheet may cover the core with the one or more protectors as if theprotectors are not present. In another aspect, the core may be indentedbut not sufficiently to accommodate the entire thickness of the one ormore protectors so that after covering with the sheet, there may be aslight bulge where the protectors are present. The slight bulge mayserve as an indicator or how to locate the holding devices. In anotherembodiment, the protectors may be added after the core is covered withthe polymeric sheet or sheets and may be flushed with the rest of theload bearing structure or protruding to form a slight bulge.

When the protectors are added prior to covering of the core by thepolymeric sheet, the core may be indented, as mentioned above, and theprotector may not be easily discernible after covering the core with thepolymeric sheet. In instances like these, some guiding features may bepresent on the load bearing structure for better positioning of theholding features such as straps used in securing the cargo. The guidingfeatures may include marking, slight bumps, protrusion or ridges forbetter defining the location for the straps.

The protectors may be constructed from any polymeric or metallicmaterials, or combinations thereof, that may be easily molded or castinto the desired shape and are rigid, substantially rigid, or possesssufficient reinforcement for the edges. In one embodiment, when theprotectors are present on the core prior to the covering of the core bythe polymeric sheet or sheets, the protectors may be made of same ormaterial having similar bonding properties as the sheet to facilitatethe bonding of the protector both to the sheet and/or core at thebonding temperature of the sheet to the core. However, as noted above,the protectors made of any other material may still be bonded to theouter edges of the sheet using the sealing feature. In anotherembodiment, when the protectors are added to the load bearing structureafter bonding of the sheet or sheets to the core, any material may beused for the protectors.

To aid to keep the protectors on the core prior to bonding and duringthe bonding process, a tacky material, for example, an adhesive ordouble-coated adhesive tape may be used. Examples of the adhesive mayinclude pressure sensitive adhesive, for example, a hot melt pressuresensitive adhesive or a non-hot melt pressure sensitive adhesive.Examples of double-coated tape may include double coated pressuresensitive adhesive tape, for example, a double-coated hot melt pressuresensitive tape or a double-coated non-hot melt pressure sensitive tape.The thickness of the adhesive or tape may be thin so that it does notcontribute to the thickness of the edge protectors substantially. Insome embodiments, the adhesive or tape may be substantially meltedduring the bonding process.

To keep the edge protectors firmly in place when the protectors arepresent after the bonding process, a structure adhesive may be used,such as those used in edge sealing described above or later, so that theedge protectors do not detach or move about during and after strappingto keep the cargo in place.

The protectors may have any thickness, as long as they provide theneeded reinforcement for the edges. Some materials possess higherrigidity than others and therefore thinner protectors may havesufficient rigidity. For those that are more flexible, thickercomponents may be needed to provide sufficient rigidity or strength towithstand the force of any cargo holding means such as straps.

The edge protectors may be manufactured by molding or casting. In oneembodiment, the edge protectors may be made in bulk and then cut tosize. In another embodiment, the edge protectors may be individuallymade to size or sizes.

Whether the load bearing structure is made with or without edgeprotectors, edge sealing as described above may be used, as notedbefore.

The bonding between the core and the polymeric sheet or sheets may beaccomplished with heat or heat and pressure, as noted above. In someembodiments, the bonding between the core and the thermoplastic sheet,and between the polymeric sheets generally includes portions of the coreproximal to its surface to be sufficiently combined with portionsproximal to the surface of the polymeric sheet, or portions of onepolymeric sheet proximal to its surface to be sufficiently combined withportions of the second polymeric sheet proximal to its surface, so thatany attempts at separating the two components may generally not resultin a clean separation of the components, but may result in some cohesivefailure near the interface. The bonding process for producing thisusually occurs at a relatively high temperature, for example, atemperature sufficient to soften the polymeric material. Thistemperature is also dependent on the type of polymer used in producingthe sheet or sheets.

When the polymeric core is covered with one polymeric sheet, the edgesof the polymeric sheet are bonded to the surface of the core with heator heat and pressure. When the core is covered with two polymeric filmsand the edges of the two films overlapped with one another, the edges ofone sheet may be bonded to the second sheet with heat or heat andpressure. Though the bonding process bonds the sheet to the core orsheet to sheet thoroughly, it may be difficult to bond the edges soperfectly that no adhesive or cohesive failure may manifest at theinterface due to, for example, some imperfection in the bonding. Also,any such failure may generally manifest more at the edges which may alsodue to repeat catching of the edges.

When the polymeric core is covered with one polymeric sheet or film, anyunbounded portions of the film may be trimmed after the bonding process.When the core is covered with two polymeric films and the edges of thetwo films overlapped with one another, any unbounded portions of thesecond film may be trimmed and removed. However, the trimming process ingeneral may not be sufficiently efficient to completely trim off theunbounded wanted portions. Some portions of the unbonded edges may beleft on the load bearing structure. For example, for the two polymericfilms to be bonded at the edge, part of the edge that is not firmlybonded may be trimmed as close to the bond line as possible, but may notbe possible to trim all the unbound portions without excessive cost orcare. For the bonding of one film to the core, it is equally difficultto trim the unbound portions. Also, though there is strong bondingbetween either the core and the polymeric film or between the twopolymeric films, as discussed above, for example, it may be difficult tobond the edges thoroughly so that no trimming is needed, any adhesive orcohesive failure at the interface due to, for example, repeat catchingof the edges and/or some imperfection in the bonding or cohesivefailure, may also generally manifest more at the edges.

For folding edges, the fold is the edge and though no trimming may bedone, some imperfection in bonding of the folded edge may still bepresent.

When the surface or surfaces are to be bonded together, the smoother ormore even they are, the more complete a bond may be formed with fewerdefects. Without wishing to be bound by a theory, it is surmised thateven though the surface or surfaces of the core and/or polymeric sheetsare made as uniformly smooth as possible, the surface or surfaces of thecore and/or of the polymeric sheets may still be uneven and may thusdefects in bonding may be present, unless costly or extraordinary stepsare taken to smooth the surface or surfaces. After manufacturing of thecore and/or sheets are completed, an easy way to smooth out the surfacesmay be by heating the surfaces to a temperature high enough to melt thesurface so that the molten material may flow to cover up any defectsthat make the surface and/or surfaces uneven or not smooth. Such hightemperature treatment may tend to damage the core and/or sheetsunnecessarily.

When such imperfection or unevenness is present on the surface orsurfaces of the core or sheets away from the edges, it is less likelyfor moisture, dirt and/or left over products from previous cargo, andmicrobes that thrive on the same to accumulate as those surfaces areless likely to be exposed to them. However, any such imperfections atthe edges may be more likely to attract moisture, dirt and/or left overproducts from previous cargo, and microbes that thrive on eithermoisture, dirt or left over products and the moisture, dirt, and/or leftover products and microbes may tend more to accumulate about the edgesand become more difficult to clean once accumulated, since theaccumulation may be more or less hidden. This may lead to contaminationof the products or cross-contamination at the least, and may also renderthe load bearing surfaces non-reusable or dangerous to re-use withoutprior vigorous decontamination if the structure is being reused forcargoes that are different from previous cargo, for example, differentfood types, such as poultry, fresh vegetables, and fresh fruits, or evensame types of products. Even new load bearing structures that are notcovered or properly stored prior to use may be susceptible tocontamination or perception of contamination. Elimination or minimizingof contamination or perception of contamination in these hidden areas istherefore important for cargoes, for example, food and drugs,electronics, or any products with exposed surfaces that may becomecontaminated.

In one exemplary embodiment, a sealing liquid may be used. The liquidmay be applied, after the core is covered and bonded by the sheet orsheets, to the edges of the interface between the core and the sheet, orto the interface of the overlapping edges of the sheets. The sealingliquid may be any liquid that may soften or dissolve to a certain degreethe polymeric material(s) of the interface between the sheet and thecore or between the sheets to promote the firmly joining of thecomponents at the edge. It may be desirable to dispense and apply thesealing liquid in a controllable manner or dosage, for example, by usinga syringe-type dispenser or other metering device, to minimizeoverflowing or dripping or wasting of the liquid, or excessivedissolution of the material in the interface. Whatever the dispensingdevice, it may be desirable that the tip of the dispensing device, forexample, the bore, be of a small cross-section, for example, just largeenough for the liquid to be dispensed. The sealing liquid may be activeat ambient temperature. The sealing liquid may be applied also prior tothe bonding of the sheet to the core or another sheet by application ofthe liquid either to the outer edges of the sheet or sheets, or the corewhere such sealing is to take place.

In another exemplary embodiment, a sealing tape may be used. The tapemay be applied to the edges of the sheet or one of the sheets or thecore (when one sheet is used) prior to the bonding of the sheet orsheets to the core, so that the heat used for the bonding of the sheetor sheets may also activate the adhesive for bonding the tape to thecore or sheet at the edges. The tape may include a non-tacky or solidheat activatable adhesive, for example, a hot melt adhesive, a heatcurable adhesive, or a reactive adhesive, on one side and a contact ortacky adhesive on the other side. The contact or tacky adhesive may becovered with a liner prior to use and the tape may be wound up in a rollduring storage. When applying to the sheet, the liner may first beseparated from the contact or tacky adhesive side and bond to at least aportion of the top surface of the core or the edge of the sheet if onesheet is used, or to at least a portion of the side of the second sheetto be bonded together to the first sheet when two sheets are used orvice versa, or be substantially simultaneously separated and appliedwith the contact or tacky adhesive side onto the side of the sheet to bebonded to at least a portion of the top surface of the core or the edgeof the sheet if one sheet is used, or to at least a portion of the sideof the second sheet to be bonded together to the first sheet when twosheets are used or vice versa, so that the heat activatable adhesiveside may be exposed prior to bonding either to the core or sheet, or tothe first sheet or second sheet.

The sealing tape may include a sheet of heat activatable adhesive withone side coated with a contact or tacky adhesive, as noted above. In oneembodiment, the heat activatable adhesive may be coated onto a liner,which forms a non-tacky adhesive sheet when cooled or dried. In oneaspect, the adhesive may be solution coated onto the liner and after thesolvent evaporates, the adhesive layer may form a non-tacky adhesivesheet. In another aspect, the adhesive may be extrusion coated onto aliner and cooled to a non-tacky adhesive sheet. In another embodiment,the heat activatable adhesive may be any film forming, for example, hotmelt adhesive, which may be cast or extruded and cooled to a non-tackyadhesive sheet.

The heat activatable adhesive may be coated with a contact or tackyadhesive on the exposed side, if the heat activatable adhesive ispresented on a liner, or on any one side, if there is no liner. Thecontact or tacky adhesive may be coated using any appropriate coatingtechnique, including but not limited to solvent coating, extrusioncoating or screen printing with patterns of dots or arrays of microdots,which may generally be densely populated. The thickness of the contactor tacky adhesive and the heat activatable adhesive may vary, but ingeneral they may be sufficiently thin so as to create a less pronouncededge after edge bonding, which may in turn minimize any tendency forseparation. The contact or tacky adhesive and the heat activatedadhesive may be selected to form a good bond between the core and apolymeric sheet at the edges or a first polymeric sheet and a secondpolymeric sheet at the edges. The contact or tacky adhesive may also beselected with good bonding characteristics to form a good bond betweenit and the hot melt adhesive layer to minimize adhesive failure at theirinterface. The tape may also help to create a smoother transition at theexposed edge at the interface and may again help to minimize anyseparation tendency at the edge. The heat activatable adhesive may beany hot melt adhesive, heat curable adhesive, reactive adhesive, etc,that is heat activated at about the same temperature as the bondingtemperature of the polymeric layer and the core, to form a good bond atthe edges, as noted above.

During application, the separation of the liner from the tacky layer maybe effected manually by peeling off the liner prior to application tothe core or polymeric sheet, or by the use of a tape dispenser that mayautomatically separate the liner from the tacky adhesive during use,simultaneously or almost simultaneously with the attachment of thecontact or tacky adhesive to the polymeric sheet.

In other embodiments, the tape may also be applied to the edgesmentioned above after the polymeric sheet or sheets have been bonded sothat the tape is present on the outside. In these embodiments, theadhesive may be a pressure sensitive or heat sensitive adhesive coatedon a backing only on one side.

In still other embodiments, one side of the tape may include a heatactivated adhesive while the other side may include a pressure and heatsensitive adhesive so that the tape may be held in place by pressureprior to heat activation during the bonding process.

In a further exemplary embodiment, a chemical sealing composition may beused. The edges of the sheet may be further bonded to the polymeric corewhen one polymeric sheet is used, or when two polymeric sheets are used,the overlapping areas of the first and second layers, with a chemicalsealing composition that may be in liquid form prior to application. Thechemical composition may be a liquid or a slurry that may be activatedby drying or at the bonding temperature during the bonding process, oran adhesive in liquid form which may be activated at about the bondingtemperature of the polymeric sheet and the core. The slurry may includea mixture of the liquid with dispersing particles of the polymericsheet. The liquid chemical sealing composition may be applied in itsnative liquid form, slurry or semi solid form, or in a treated solidform. While the liquid in its native form may be applied in a similarmanner as the sealing liquid as noted above. Treated slurry may bepainted on or dispensed from a container, such as a squeeze bottle, asabove, but with a larger opening on its dispensing end onto either theedges of the polymeric sheet either prior to or after the bondingprocess between the core and the sheet. When applied prior to thebonding process, the composition may aid to adhere the sheet to the coreor the sheet to the sheet with the liquid and the particles may beactivated during the bonding process. When the treated chemical sealingcomposition is in a solid form, it may include small encapsulatedparticles, encapsulating the liquid inside. The application of the solidform may include the use of a device for sprinkling the treated chemicalcomposition onto the edges prior to the bonding process between the coreand the polymeric sheet or sheets. In either form, the chemical sealingcomposition may be activated during the bonding process of bonding thepolymeric core with the polymeric sheet or sheets, if desired.

The treatment material used to form the chemical sealing composition inthe treated solid form may render it free flowing, i.e., the treatedform does not adhere to each other, but may adhere to the core or sheetsufficiently, even if temporarily prior to the bonding process.

An example of slurry composition may include a mixture of a sealingliquid noted above mixed with heat activatable polymeric powder, such aswith same or similar powder polymeric material used in the manufacturingof the polymeric sheet. For example, when the polymeric sheets are madefrom high impact polystyrene, then the powder is powdered polystyrene.The sealing liquid may be relatively non-volatile so that the liquid isnot substantially evaporated prior to the bonding process between thesheet with the core and/or sheet.

As discussed in more detail below, a chemical sealing composition mayalso include a self-healing and/or self-repairing composition. Theself-healing and/or self-repairing composition may also be present inany of the other sealing features.

In yet another exemplary embodiment, the edges may be sealed by amechanical and/or heat sealing device, for example, an ultrasonicsealing device. For example, ultrasonic energy produced by, for example,an ultrasonic horn and/or an ultrasonic welder may be used. Theultrasonic energy level may be selected so as to affect, but not todistort the edges being bonded.

In some embodiments, the first and second polymeric sheets may bepartially folded over each other as they are bonded to the polymericcore, and the folded area may be subjected to heat, pressure and/or avacuum to create a sealed joining area. Excess material of the polymericsheets may also be trimmed off away from the load surface.

In one embodiment, the polymer sheet or film layer may include anantimicrobial agent having some surface activity therein. In anotherembodiment, an antimicrobial coating having some surface activity may beapplied to at least one of the exposed surfaces of the load bearingstructure, whether or not the surface is covered by a sheet or filmlayer. The antimicrobial agent may be in powder form or in liquid form.In any of the forms, the antimicrobial agent may be able to withstandthe bonding temperature without degrading or losing its properties.

According to one embodiment, the polymeric film or sheet layer coveringthe core may have anti-microbial properties. In one aspect, thepolymeric layer, for example, a high impact polymeric sheet may coverthe bottom side, the entire thickness of the width and a portion of thetop surface of the core. In another aspect, the polymeric film or sheetlayer, for example, a high impact polymeric sheet having antimicrobialproperties may cover the top and bottom side and substantially all ofthe thickness of the width of the core.

In one exemplary embodiment, at least one antimicrobial agent havingsome surface activity may be added to the material used for making thesheet. The antimicrobial agent may be in powder form or in liquid form.In another exemplary embodiment, at least one antimicrobial agent havingsome surface activity may be coated onto the exposed surface or surfacesof the load bearing structure, whether or not the surface is covered bya sheet or film layer. The antimicrobial agent may be in powder form orin liquid form. In any of the forms, the anti-microbial agent may becapable of withstanding the bonding temperature of the sheet or sheetsto the core without degradation of its anti-microbial properties.

In another embodiment, a porous surface, which may be a porous sheetsubstrate discussed above, or surface of the polymeric core, forexample, an expanded polystyrene core or polyurethane core, which may becovered with one polymeric sheet in a way that part of the top surfaceof the core may be exposed. The polymeric sheet may be impregnated witha water based antimicrobial composition having at least one polymericcarrier that may be in the form of an emulsion or dispersion and atleast one substantially non-leaching antimicrobial component that issubstantially free of environmentally hazardous material. The poroussurface may or may not be further over coated or protected with a filmlayer after being impregnated with the antimicrobial composition.

In yet another embodiment, a porous surface, which may be a porous sheetsubstrate, may be impregnated with a water based antimicrobialcomposition, having at least one polymeric carrier that may be in theform of an emulsion or dispersion and at least one surface activeantimicrobial component that is substantially free of environmentallyhazardous material.

In still another embodiment, a non-porous sheet substrate may be coatedwith a water based antimicrobial composition, having at least onepolymeric carrier that may be in the form of an emulsion or dispersionand at least one substantially non-leaching antimicrobial component thatis substantially free of environmentally hazardous material.

For load bearing structures having one thermoplastic sheet over the corethereon, the exposed surfaces may be porous, as noted above. The porousmaterial may be impregnated with a water based antimicrobialcomposition, also as mentioned above, the antimicrobial composition mayitself form a film making the surface non-porous.

In some embodiments, the surfaces of the porous materials impregnatedwith an antimicrobial composition may be non-porous after drying orsetting and may perform as if it has been coated or covered with athermoplastic sheet or protective sheet mentioned above.

The same emulsion or dispersion mentioned above may also be coated ontothe exposed surfaces of load bearing structures having two thermoplasticsheets over the core thereon, when the exposed surfaces are non-porous.

In any of the above disclosed embodiments, the antimicrobial agent maybe added after the heat bonding process. In the embodiments where heatbonding is effected after the antimicrobial agent is added, theantimicrobial agents used may be capable of retaining or not losing itsanti-microbial properties during the bonding process.

In any of the embodiments with anti-microbial properties, edge bondingmay be effected either before or after coating with the antimicrobiallayer.

The antimicrobial agent may aid in minimizing the accumulation ofmicrobes on the load bearing structure. However, the edge sealing andantimicrobial agent may aid in minimizing the accumulation of dust, dirtor microbes.

In other embodiments, the core may include a structural metal mesh toresist piercing of the surface.

In a further embodiment, load bearing structures discussed above, havingantimicrobial properties, and/or puncture resistant properties may alsohave fire retardant properties and/or ultra violet light barrierproperties.

In one embodiment of the invention, a load bearing structure discussedabove may be a dunnage platform having a top side, and a bottom sideseparated from each other by a width having a thickness. The platformmay be of a substantially square or rectangular shape. A container maybe assembled from a plurality of loading bearing structures such asdunnage platforms, each having a light weight polymeric core and a highimpact polymeric sheet substantially covering the core, as discussedabove. The dunnage platforms useful for assembling into a container mayinclude interconnecting features which mate together to form acontainer.

The edges of the load bearing structures of the container may be bondedwith a sealing tape, a sealing chemical composition, a sealing liquid,or a mechanical and/or heat seal, such as with an ultrasonic sealingdevice, as discussed above.

In one embodiment, when the load bearing structures discussed above maybe assembled into a container having a base, top and walls, theextensions may be present in one or more of the base, top and walls.

The sheet or film layer covering the core of each of the walls, top andbase of the container may also include anti-microbial propertiesdescribed above. The walls may or may not include supports. In oneexemplary embodiment, at least one antimicrobial agent having somesurface activity may be added to the material used for making thepolymeric sheet or film layer, for example, a high impact polymericsheet. The antimicrobial agent may be in powder form or in liquid form.In another exemplary embodiment, at least one antimicrobial agent havingsome surface activity may be coated onto the exposed surface or surfacesof the sheet. The antimicrobial agent may be in powder form or in liquidform.

In any of these forms, the anti-microbial agent may be capable ofretaining its properties during the bonding process.

In some aspects, a container that is light weight, strong, and assembledfrom a plurality of movable load bearing structures discussed above, mayalso be puncture resistant and/or having fire retardant propertiesand/or ultra violet light barrier properties, with or withoutantimicrobial properties.

One of the load bearing structures or dunnage platforms of the containermay also have a plurality of feet extending from the bottom side of thestructure, as noted above.

In another embodiment of the invention, the load bearing structuresdiscussed above may be in the form of a substantially L-shapedcross-section, having an inner surface and an outer surface joined by awidth having a thickness. The surfaces of the polymeric core may bepartially or completely covered by a polymeric sheet. The edges of thesheet or sheets may be sealed with a tape, a sealing liquid, a sealingchemical composition or a mechanical and/or heat seal, which may includethe use of an ultrasonic sealing device, as discussed above.

In one embodiment, a container may include two identical or mirrorimages substantially L-shaped cross-section halves each having at leasttwo walls and a base or top component, each of the components havingcorresponding interlocking features to be mated together to form acontainer having for example, a closed enclosure therein. The foot printof the container is not larger than one of the substantially L-shapedcross-section halves.

One of the L-shaped load bearing structures or dunnage platforms of thecontainer may also have a plurality of feet extending from the bottomside of the structure.

In still another embodiment of the invention, the load bearing structurediscussed above may be in the form of a clam shell having an innersurface and an outer surface joined by a width having a thickness. Thesurfaces of the polymeric core may be partially or completely covered bya polymeric sheet. The edges of the sheet or sheets may be sealed with atape, a sealing liquid, a sealing chemical composition or a mechanicaland/or heat seal, which may include the use of an ultrasonic sealingdevice, as discussed above.

A container may include two clam shell halves, in mirror images, eachhaving at least one wall and a base or top component, each of the halveshaving corresponding interlocking features to be mated together to forma container having for example, a closed enclosure therein. Thecontainer may also include a plurality of supports.

In either of the above embodiments where the load bearing structure maybe in the form of a substantially L-shaped cross-section having at leasttwo walls and a base or top component, or a clam-shell half and thecontainers may be assembled from the same, or mirror images of the same,each of the components having corresponding interlocking features to bemated together to form a container having an enclosure therein, Theedges of the halves may also be sealed as discussed above. In oneaspect, the footprint of the knock-down or collapsed container is notlarger than the foot-print of each of the L-shaped or clam shell halves.In another aspect, the footprint of the knock-down or collapsedcontainer is larger than the footprint of each of the L-shaped or clamshell halves.

In one embodiment, each half may be made of an inner light weight corecovered by at least one layer of strengthened film or sheet. In oneaspect, the layer of strengthened sheet or film may includeantimicrobial properties, as discussed above. In another embodiment, thecore may include antimicrobial properties, as discussed above.

In some embodiments, a structural metal mesh may be inserted into thecore to resist piercing of the surface. The container may also have fireretardant properties and/or ultraviolet light barrier properties

The load bearing structure of the present invention may be useful forloading, storing or transporting products that either cannot toleratesuch contamination or cross-contamination, susceptible to spoilage, orin situations that the perception of non-cleanliness is not desirable.The present invention also relates to a load bearing structure for usedirectly in clean rooms for the manufacturing of electronic parts,micro-electronic devices, drugs and pharmaceuticals, food products suchas snacks, or similar products that need to be kept clean from dust,dirt or microbes. The cargo may be directly loaded after making withoutadditional steps of transferring the cargo to a load bearing structureafter the cargo leaves the clean room, thus eliminating steps, savingtime, minimizing manpower or robotics, or risk of contamination ordamage. The edge sealing further adds to the cleanliness of the loadbearing structures.

According to one embodiment, the container may include an enclosurehaving one undivided internal compartment. According to anotherembodiment, the container may include an enclosure having more than oneinternal compartment. In one aspect, the interior may have dividersmolded into the side of the component structures. In another aspect, thedividers may be added to the container to form separate compartments.Channels or depressions may be present or molded into the components ofthe container to allow for placement of external dividers to adjust thesize of the compartments.

According to one embodiment, features may be present or formed into thecomponents of the container for placement of cargo or placement of othercomponents for more secure location of cargo. According to anotherembodiment, the channels or depressions mentioned above may be used tolocate the features.

In one aspect, the containers may be made of the size and shape toaccommodate the cargo. In another aspect, the cargo may be contained inits own packaging and then inserted into the container. In a furtheraspect, features may be located in the container to aid in accommodatingthe cargo.

The present invention further relates to containers for shipping and/orstorage of cargo in which the climate within the container iscontrolled.

According to the present invention, the polymeric core, for example, maybe a closed cell foam core such as an expanded polystyrene core with aregion proximal to its surface that is combined with a high impactpolymeric sheet, for example, a polystyrene sheet, by heat and pressure.In one exemplary embodiment, at least one antimicrobial agent havingsome surface activity may be added to the material used for making thesheet. The antimicrobial agent may be in powder form or in liquid form.In another exemplary embodiment, at least one antimicrobial agent havingsome surface activity may be coated onto at least one of the exposedsurfaces of the sheet. The antimicrobial agent may be in powder form orin liquid form.

The load bearing structures may also include a plurality of supports, asdescribed above, which may generally space the bottom surface of theload bearing structure from the ground and/or other support surface. Thesupports may also be spaced from each other such that, for example, theload bearing structure may be manipulated with a forklift and/or othermoving machinery fitting into the spaces between the supports. In someembodiments, runners, bridges and/or other connectors may also beincluded, such as, for example, connecting multiple supports, which maygenerally increase the strength and/or rigidity of the base. The runnersor bridges may be manufactured from any suitable material. For example,the runners or bridges may be constructed from wood, metal and/orvarious plastics materials, including polyolefins, HIPS, polyesters,lead free PVC or any of the materials suitable for the polymeric sheetmentioned above. In some embodiments, the runners or bridges aremanufactured from HIPS (high impact polystyrene) using an extrusionforming process. Further, the bridges may be configured so that theyeach span two or more supports of a row and may be affixed to the endsof the supports so that they interconnect. For example, the bridges maybe affixed using a suitable adhesive. In addition, the bottom of thesupports for affixing the bridges may include indentations for retainingthe bridges so that the bridges are not protruded from, but flushed withthe bottom of the supports.

The runners or bridges may extend between adjacent supports. In oneembodiment, the bridges may be a plurality of wear resistant membersthat are affixed to an underside of at least some of said supports andwhich are adapted in use to bear against a foundation upon which theload bearing structure may rest. Further, the runners or bridges may beconfigured so that they each span two or more supports of a row and maybe affixed to the end walls of each of the supports so that theyinterconnect same. For example, the runner or bridges may be affixed toabutting end walls using a suitable adhesive.

The load bearing structures may also include anti-skid members orfurther strengthening features, for example, the bottom surface of theload bearing structure, or base if it is used as a component of acontainer, and/or the supports may also include ridges, ribs,reinforcements and/or other surface modifications to which may, forexample, aid in increasing the strength and/or rigidity of the structureof the base, especially under load. Some modifications also aid inreducing any unintended slippage of the container while at rest. In someaspects, the modifications may be roughening the bottom surface toreduce slippage. It is also believed that the ability of the supportsand/or base to resist compressive loads may be greatly enhanced if eachof the side walls includes a plurality of generally longitudinallyextending ribs.

Other objects, features and advantages of the invention should beapparent from the following description of a preferred embodimentthereof as illustrated in the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 and 1 a are perspective views of a top side of a core of a loadbearing structure with extensions or supports and without, respectively,that is in accordance with the invention;

FIGS. 2 and 2 a are perspective views of a bottom side of the core ofFIGS. 1 and 1 a, respectively;

FIG. 3 shows a line drawing of a loaded cargo carrier dunnage platformwith a half enclosure positioned on the cargo carrier dunnage platform,according to an embodiment of the invention;

FIG. 3A shows a line drawing of the cargo carrier dunnage platform withphase change material containers positioned in pockets;

FIG. 4 are shows an embodiment of a load bearing structure of thepresent invention;

FIG. 4A shows a line drawing of the empty cargo carrier dunnage platformwith a half enclosure positioned on the cargo carrier dunnage platform,according to an embodiment of the invention;

FIG. 4B shows a line drawing of a closed cargo carrier dunnage platformwith a both-half enclosures positioned on the cargo carrier dunnageplatform, according to an embodiment of the invention

FIGS. 5-7 show embodiments of a container of the present inventionduring assembly;

FIG. 8 shows an embodiment of a container of the present inventionduring assembly, depicting the interconnecting features;

FIGS. 8A-8E show embodiments of a container of the present inventiondepicting the interconnecting features during assembly;

FIG. 9 shows a line drawing of the empty cargo carrier dunnage platformwith a half enclosure positioned on the cargo carrier dunnage platform,according to another embodiment of the invention;

FIG. 10 shows an L-shaped half of an embodiment of the container of thepresent invention having features for locating cargo or partitions;

FIG. 10A show a full view of the inside bottom of an embodiment of thecontainer of the present invention having features for locating cargo orpartitions;

FIG. 11 shows fully assembled container of an embodiment of the presentinvention;

FIG. 11A shows an L-shaped half of an embodiment of the container of thepresent invention having features for locating cargo;

FIGS. 12, 12 a-12 g illustrate embodiments of a load bearing structurewith extensions or supports of the present invention with at least onepolymeric sheet bonded to it and with a sealing feature for the edges ofthe polymeric sheet;

FIGS. 12h-12m illustrate an embodiment of a load bearing structure ofthe present invention with two polymeric sheets bonded to it and with afolded sealing feature for the edges of the polymeric sheets;

FIGS. 13 and 13 a illustrate a method of sealing a polymeric sheet to apolymeric core using a sealing liquid in an embodiment of the invention;

FIGS. 14, 14 a and 14 a-l illustrate embodiments of using a tape as asealing feature in embodiments of the present invention;

FIGS. 14b and 14c illustrate application of a tape at the edge of apolymeric sheet bonded to a polymeric core of a load bearing structurein an embodiment of the present invention;

FIG. 14d illustrates a one-sided tape at the edge of a polymeric sheetbonded to a polymeric core of a load bearing structure in an embodimentof the present invention;

FIG. 14e illustrates the edge of a single polymeric sheet bonded to apolymeric core of a load bearing structure in an embodiment of thepresent invention;

FIGS. 15-15 h illustrate embodiments of a load bearing structure withoutextensions or supports of the present invention with at least onepolymeric sheet bonded to it and with a sealing feature for the edges ofthe polymeric sheet;

FIGS. 16 and 16 a illustrate an embodiment of a container with tongueand groove interfaces in an embodiment of the present invention;

FIGS. 17 and 17 a illustrate a base of the embodiment of a container ofFIGS. 16 and 16 a;

FIGS. 18, 18 a and 18 e illustrate a wall panel of the embodiment of acontainer of FIGS. 16 and 16 a;

FIGS. 18 b, 18 c and 18 d illustrate a wall panel interfacing with a toppanel, another wall panel and a base, respectively in an embodiment ofthe present invention;

FIGS. 19 and 19 a illustrate a top panel of the embodiment of acontainer of FIG. 16;

FIG. 20 illustrates the assembly of the embodiment of a container ofFIG. 16;

FIGS. 21 and 21 a-e illustrate embodiments of the present invention ofbases with different extensions or supports;

FIGS. 22, 22 a and 22 b illustrate integrally formed or joined wallpanels in a substantially L-shaped configuration for interfacing with atop panel and a base in an embodiment of the present invention;

FIGS. 23, 23 a and 23 b illustrate a pair of integrally formed or joinedwall panels in a substantially L-shaped configuration, one of which isintegrally formed or joined with a top panel and the other of which isintegrally formed or joined with a base in another embodiment of thepresent invention;

FIGS. 24 and 24 a-24 c illustrate a load bearing structure withdepressions for accommodating edge protectors to accommodatecargo-holding items in an embodiment of the present invention;

FIG. 24d illustrates a load bearing structure with extensions orsupports and depressions for accommodating edge protectors without guidegrooves in an embodiment of the present invention;

FIG. 24e illustrates a load bearing structure with depressions foraccommodating edge protectors without guide grooves or extensions orsupports in an embodiment of the present invention;

FIG. 25 illustrates a load bearing structure with edge protectors and aguiding groove in an embodiment of the present invention;

FIGS. 25 a, 25 b and 25 c show partial cross-section views of loadbearing structures with examples of edge protectors sitting indepressions in an embodiment of the present invention;

FIGS. 26 and 26 a illustrate examples of L- and C-shaped edgeprotectors, respectively in embodiments of the present invention; and

FIGS. 27 and 27 a illustrate a load bearing structure with edgeprotectors with guide features in embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The detailed description set forth below is intended as a description ofthe presently exemplified systems, devices and methods provided inaccordance with aspects of the present invention and are not intended torepresent the only forms in which the present invention may be preparedor utilized. It is to be understood, rather, that the same or equivalentfunctions and components may be accomplished by different embodimentsthat are also intended to be encompassed within the spirit and scope ofthe invention. Unless defined otherwise, all technical and scientificterms used herein have the same meaning as commonly understood to one ofordinary skill in the art to which this invention belongs. Although anymethods, devices and materials similar or equivalent to those describedherein can be used in the practice or testing of the invention, theexemplary methods, devices and materials are now described. Allpublications mentioned herein are incorporated herein by reference forthe purpose of describing and disclosing, for example, the designs andmethodologies that are described in the publications which might be usedin connection with the presently described invention. The publicationslisted or discussed above, below and throughout the text are providedsolely for their disclosure prior to the filing date of the presentapplication. Nothing herein is to be construed as an admission that theinventors are not entitled to antedate such disclosure by virtue ofprior invention.

In FIG. 1, an expanded polymer core 10 a, for example, a polystyrenecore, is in the general shape of a rectangular slab with a width 12(FIG. 1) that has a thickness 14 a which may be of any dimension, forexample, approximately one and three-fourths to about two inches (about4.5 cm to about 5 cm). The core 10 a may have a smooth topside 16 awhich may be partially or completely covered with a polymeric layer, forexample, a high impact polymeric sheet 67, such as a high impactpolystyrene sheet, that may be in the order of approximately four feetlong and forty inches wide. The smooth topside 16 a may generallytransition to the width 12 at its periphery with edge 12 a. A bottomside 18 a, as shown in FIG. 2 of the core 10 a may include extensions orsupports 20-28, though most of the embodiments may not include aplurality of extensions or supports. These extensions or supports, ifpresent, may extend for a length, for example, approximately four to sixinches (about 10 cm to about 20 cm) therefrom. Referring to FIG. 2, theedge 12 a is proximal to spaces 42, 44, 46, 48 on the bottom side 18 a.The marginal spaces 42, 44, 46, 48 separate the extensions or supports26-28, the extensions or supports 20, 23, 26, the extensions or supports20-22 and the extensions or supports 22, 25, 28, respectively, from theedge 12 a.

FIGS. 1a and 2a are embodiments similar to FIGS. 1 and 2, but without aplurality of extensions or supports.

The load bearing structure 10 also has a width 12 having a thickness 14,which is the combined total thickness of the core 10 a and sheet 67,mentioned above. Cargo may be loaded on the top side 16 a of the loadbearing structure 10. The cargo may be perishable or non-perishable andmay include food such as fresh vegetables and fruits, poultry and meatproducts, pharmaceuticals and drugs, electronic components and devices,etc.

Moisture, dirt and/or left over products and microbes that thrive oneither moisture, dirt or left over products may cause contamination ofthe products or cross-contamination at the least, and may also renderednon-usable or dangerous to re-use without prior vigorous decontaminationwhen the structure is being reused for cargoes that are different fromprevious cargo, for example, different food types, such as poultry,fresh vegetables, and fresh fruits, or even same types of products. Evenif the load bearing structures are newly made, dirt and/or moisture andmicrobes that thrive on either dirt or moisture may cause contaminationof the cargo loaded on the structure. The dirt and/or moisture andmicrobes may tend to hide, grow or accumulate in interfaces betweenlayers of materials if there is imperfect joining and/or bonding of thelayers.

In general, during the normal bonding of the polymeric film to thepolymeric core, heat and/or pressure is used so that portions of thepolymeric core proximal to the surface of the bottom side 18 a withportions of the polymeric sheet 67 proximal to the surface of the bottomside of the sheet 67 to form a substantially strengthened composite.Additionally, a portion of the polymeric core that is proximal to theedge 12 and in a proximal relationship to the bottom side 18 a iscombined with portions of the polymeric sheet 67.

However, even though the bonding between the bulk of the polymeric coreand the polymeric sheet is sufficiently strong, with or withoutimperfections, to produce a strengthened load bearing structure, theneed to improve the bonding between the peripheral of the polymericsheet and the polymeric core may still be present to minimize oreliminate any imperfections where the dust, dirt and/or moisture andmicrobes may tend to hide, grow or accumulate, generally in interfacesbetween layers of materials if there is imperfect joining and/or bondingof the layers.

The load bearing structure or the platform 10, as shown in FIG. 1, 1 a,2 or 2 a, may include a light weight polymeric core 10 a, covered byeither one polymeric sheet or two polymeric sheet 67, as discussedabove, and the interface between one polymeric sheet 67 or 68 (as shownin FIGS. 12 and 15) and the surface of the core, or the interface of theedges formed by the overlapping and/or abutment of one polymeric sheetwith a second polymeric sheet may be sealed with sealing feature, suchas a sealing liquid, a heat activatable adhesive, a sealing chemicalcomposition, or a mechanical and/or heat seal, and may include anultrasonic sealing device to minimize or eliminate areas where moisture,dirt and/or left over products and microbes that thrive on eithermoisture, dirt or left over products may hide, grow and/or accumulate.

Any application of the sealing feature is close to the outer edges ofthe polymeric sheet or sheets, at the, for example, peripheral of theouter edges of the polymeric sheet 67 or sheets, 67, 68. It issufficient that a relatively small portion of the outer edges may besealed by the sealing feature, though a larger portion may also besealed. For example, about 4 millimeters to about 12 millimeters fromthe edge, more for example, about 5 millimeters to about 10 millimetersfrom the edge, and more for example, about 5 millimeters to about 8millimeters from the edge, of a polymeric sheet is sealed with thesealing feature. The rest of bonded area of the polymeric sheetincluding the outer edges is bonded with heat and/or pressure in themanufacturing process of the load bearing structure, as noted above. InFIGS. 13 and 13 a, for example, the sealing feature is present at about7 millimeters from the outer edge of the second sheet 68.

Examples of heat activatable adhesives may include, but not limited toadhesives containing ethylene alpha olefin interpolymers, such as thosedisclosed in U.S. Pat. Nos. 6,319,979, 6,107,430 and 7,199,180;Metallocene based adhesive including those containing substantiallylinear ethylene/1-octene copolymer, available from The Dow ChemicalCompany, those disclosed in U.S. Pat. Nos. 8,222,336 and 8,163,833;Metallocene hot melt adhesive including those disclosed in U.S. Pat. No.8,476,359; propylene based hot melt adhesive including those containingnonmetallocene, metal-centered, heteroaryl ligand-catalyzed propyleneand ethylene copolymer adhesives; reactive hot melt adhesive asdisclosed in U.S. Pat. No. 8,507,604; heat activated hot melt adhesivesincluding those disclosed in U.S. Pat. Nos. 8,475,046 and 8,240,915;adhesives containing metallocene and non-metallocene polymers, such asthose disclosed in U.S. Pat. No. 8,475,621; adhesives containingethylene .alpha.-olefin, such as those disclosed in U.S. Pat. No.6,107,430; hot melt adhesives containing block copolymers, such as thosedisclosed in U.S. Pat. No. 8,501,869; Polyolefin adhesives such as thosedisclosed in U.S. Pat. Nos. 8,283,400 and 8,242,198, all of which arehereby incorporated by reference in their entirety.

The sealing liquid may be any solvent that may slightly dissolve thecore and/or the polymeric sheet during sealing, provided the liquid isnot toxic. It is also desirable that the liquid has a moderate to high asolubility index for the core and/or the polymeric sheet, so that asmall amount of the liquid is adequate. The liquid may be slightlyvolatile or relatively non-volatile at ambient temperature. Examples mayinclude chlorinated solvent such as Tetrachloroethylene; or somecyanoacrylate compositions. The liquid may be applied to the edges ofthe interface between the polymeric sheet and core or between twopolymeric sheets via a dispensing device, as discussed above. An exampleis shown in FIG. 13. The application may be performed after the bondingprocess, especially if the liquid is relatively volatile and driesrelatively quickly at ambient temperature.

The sealing chemical composition may include any liquid that isrelatively non-volatile and may be in the form of a liquid, a treatedform such as a semi-liquid composition including a mixture of liquid andsolid particles, or a slurry, a solid form such as a capsule of anyliquid adhesive or sealing composition. Examples of useful liquidadhesives may include those containing cyanoacrylate or derivatives, orchlorinated solvents noted above mixed with polymeric particles.

Treated sealing chemical compositions such as a slurry may be lessvolatile than pure solvents or even chemical compositions and thus maybe amenable to be painted on in addition to being dispensed from adispensing device such as a container like a squeeze bottle or asyringe, as above, but with a larger opening on its dispensing end ontoeither the edges of the polymeric sheet either prior to or after thebonding process between the core and the sheet, depending on theactivation temperature of the composition. In some embodiments, theslurry composition may include a mixture of a sealing liquid noted abovewith same or similar powder polymeric material used in the manufacturingof the polymeric sheet. For example, when the polymeric sheets are madefrom high impact polystyrene (HIPS), the powder may include powderedpolystyrene. The sealing liquid may be relatively non-volatile so thatthe liquid is not substantially evaporated prior to the bonding processbetween the sheet with the core and/or sheet. One example may include asolvent mixed with a solid, such as tetrachloroethylene solvent mixedwith HIPS powder, to form a slurry which may be applied as noted above.This slurry may dry after application and the particles may, forexample, aid in sealing if heat activated in a later stage.

When the treated chemical sealing composition is in a solid form thatmay include small encapsulated particles, encapsulating any liquid thatmay be a solvent, a slurry or a sealing composition, inside, and theactivation may be the application of pressure or heat and pressure, tocrush or melt the capsules and release the adhesive.

FIGS. 12, 12 a-f illustrate a section of an example of a load bearingstructure 10 with extensions or supports, such as that described andshown in FIGS. 1 and 2, and FIGS. 15-15 h illustrate a section of anexample of a load bearing structure 10 without extensions or supports,such as that described and shown in FIGS. 1a and 2 a, or others notpreviously described, which may also include a lightweight polymericcore 10 a with a width 12. The load bearing structure 10 may furtherinclude at least one polymeric sheet, as discussed above, such as thepolymeric sheets 67, 68 as illustrated, and may also include at leastone sealing feature 70 or 80 for sealing the edges of the polymericsheets 67, 68 to each other and/or to the polymeric core 10 a, as may bethe case as illustrated. In general, the sealing of the polymeric sheetsto the polymeric core and/or to each other may be applied in anidentical and/or similar manner to any of the load bearing structuresand/or containers described herein.

FIGS. 12 and 15 illustrates an embodiment of a load bearing structure 10with a first polymeric sheet 67 and a second polymeric sheet 68 whichmay abut at an interface with each other at abutment 69. The abutment 69may generally be formed by the edges 67 c, 68 c of the polymeric sheets67, 68, respectively, and may be a flush interface, or it may includesome gap(s) and/or unevenness which may, for example, result from themanufacturing and/or joining process of bonding the polymeric sheets 67,68 to the polymeric core 10 a, as discussed above. In some embodiments,as illustrated in FIGS. 12 and 15, a sealing feature 80 may be utilizedto seal and/or cover the abutment 69 between the two polymeric sheets67, 68. The sealing feature 80 may generally cover and/or fill in anygap(s) and/or unevenness that may be present at the interface and mayalso generally extend a given amount onto each polymeric sheets 67, 68to, for example, produce a more substantial and/or durable seal. Ingeneral, a sealing feature that covers the abutment 69, such as thesealing feature 80 as illustrated in FIGS. 12 and 15, may be appliedafter the polymeric sheets 67, 68 are bonded to the polymeric core 10 a,as the sealing feature 80 lies atop the polymeric sheets 67, 68. Thesealing feature useful for this application may include any of thosementioned above, for example, a sealing tape which may include anadhesive surface on one side of the tape.

The sealing feature may also lie between the sheets 67, 68 at the edge,similar to that in FIGS. 12e and 15e where the sealing feature 70 isshown. The sealing feature 70 may be any of those listed above, forexample, a double-side coated sealing tape, a sealing liquid, a sealingchemical composition, a mechanical and/or heat seal, which may includean ultrasonic seal.

In other embodiments, as illustrated in FIGS. 12 a, 12 b, 15 a and 15 b,a load bearing structure 10 may include a single polymeric sheet 67which may extend and wrap around the entire thickness 14 a (as in FIGS.1 and 1 a) of width 12 of the polymeric core 10 a, or even extending toportions of the top surface 16 of the core, as illustrated in FIGS. 12aand 15 a, or abut at the width 12 of the polymeric core 10 a, asillustrated in FIGS. 12b and 15 b. The edges 67 a or 67 b of thepolymeric sheet 67 may be sealed to the polymeric core 10 a by a sealingfeature 70 which may be disposed between the polymeric sheet 67 and thepolymeric core 10 a, as illustrated in FIGS. 12 a, 12 b, 15 a and 15 b.The sealing feature 70 may, for example, be applied to the polymericcore 10 a prior to bonding the polymeric sheet 67. The sealing feature70 may also, for example, be applied to the polymeric sheet 67 andbonded to the polymeric core 10 a at the same time as the polymericsheet 67. In another example, the sealing feature 70 may be appliedbetween the edges 67 a, 67 b of the polymeric sheet 67 and the polymericcore 10 a after the polymeric sheet 67 has already been bonded to thepolymeric core 10 a. For example, the sealing feature 70 may includesealing liquid, chemical sealing composition, adhesive tape, etc., asdiscussed above, and may be inserted, injected, pressed-in and/orotherwise interposed between the polymeric sheet 67 and the polymericcore 10 a. In another example, the sealing feature 70 may be provided bya heat sealing or may be an ultrasonic sealing device.

In still other embodiments, as illustrated in FIGS. 12 c, 12 d, 15 c and15 d, a load bearing structure 10 with a single polymeric sheet 67 mayabut at the width 12 of the polymeric core 10 a, as illustrated in FIGS.12c and 15 c, or wrap around the width 12 of the polymeric core 10 a, asillustrated in FIGS. 12d and 15 d. The edges 67 a, 67 b of the polymericsheet 67 in FIGS. 12d and 12 c, or 15 d and 15 c, respectively, may be aflush interface, or it may include some gap(s) and/or unevenness whichmay, for example, result from the manufacturing and/or joining processof bonding the polymeric sheet 67 to the polymeric core 10 a. A sealingfeature 80 may then be utilized to seal and/or cover the edges 67 a, 67b of polymeric sheet 67 and extend onto the polymeric core 10 a. Thesealing feature 80 may generally cover and/or fill in any gap(s) and/orunevenness that may be present at the interface and may also generallyextend a given amount onto the polymeric sheet 67 and/or onto thepolymeric core 10 a to, for example, produce a more substantial and/ordurable seal. In general, a sealing feature that covers the edge of thepolymeric sheet and part of the polymeric core 10 a, such as the sealingfeature 80 as illustrated in FIGS. 12 c, 12 d, 15 c and 15 d, may beapplied after the polymeric sheet 67 is bonded to the polymeric core 10a, as the sealing feature 80 lies atop the polymeric sheet 67. Thesealing feature may include any of those mentioned above, for example, asingle side coated tape.

FIGS. 12e and 15e illustrates an embodiment of a load bearing structure10 with a first polymeric sheet 67 and a second polymeric sheet 68 whichmay abut at an interface with each other at abutment 69. The abutment 69may generally be formed by the edges 67 c, 68 c of the polymeric sheets67, 68, respectively, and may be a flush interface, or it may includesome gap(s) and/or unevenness which may, for example, result from themanufacturing and/or joining process of bonding the polymeric sheets 67,68 to the polymeric core 10 a. In some embodiments, as illustrated inFIGS. 12e and 15 e, a sealing feature 80 may be utilized to seal theedges 67 c, 68 c to the polymeric core 10 a at the abutment 69 betweenthe two polymeric sheets 67, 68. The sealing feature 80 may generallycover and/or fill in any gap(s) and/or unevenness that may be present atthe interface and may also generally extend a given amount between thepolymeric sheets 67, 68 and the polymeric core 10 a. The polymericsheets 67, 68 may also be pressed into the sealing feature 80 at theedges 67 c, 68 c to, for example, aid in filling in any gap(s) and/orunevenness at the abutment 69. In general, a sealing feature beneath theabutment 69, such as the sealing feature 80 as illustrated in FIGS. 12eand 15 e, may be applied before the polymeric sheets 67, 68 are bondedto the polymeric core 10 a, as the sealing feature 80 lies beneath thepolymeric sheets 67, 68. The sealing feature 80 may include a sealingliquid, a sealing composition or a sealing tape and may also, in anotherexample, be inserted, injected, pressed-in and/or otherwise interposedbetween the polymeric sheets 67, 68 and the polymeric core 10 a afterthe polymeric sheets 67, 68 are bonded to the polymeric core 10 a. Instill another example, the sealing feature 80 may also be applied to oneor both of the polymeric sheets 67, 68 prior to bonding and may thusbond to the polymeric core 10 a at the same time the polymeric sheets67, 68 are bonded to the polymeric core 10 a. The sealing feature mayinclude any of the above mentioned features, for example, a double sidecoated tape, a sealing liquid, a chemical sealing composition, a sealproduced by a mechanical and/or heat sealing device, including anultrasonic sealing device.

FIGS. 12f and 15f illustrate an embodiment of a load bearing structure10 with a first polymeric sheet 67 and a second polymeric sheet 68 whichmay interface with each other at an overlap 69′. The overlap 69′ maygenerally be formed by one of the edges 67 c, 68 c of the polymericsheets 67, 68, respectively, overlapping the other, as illustrated withedge 68 c lying atop edge 67 c and may result, for example, from asecond polymeric sheet being bonded to the polymeric core 10 a after afirst polymeric sheet. In some embodiments, as illustrated in FIGS. 12fand 15 f, a sealing feature 70 may be utilized to seal an edge of apolymeric sheet to the polymeric core 10 a, and/or to seal one edge of apolymeric sheet to the edge of the other polymeric sheet, such as theedge 68 c to the polymeric core 10 a and the edges 67 c, 68 c to eachother, as illustrated. The sealing feature 70 may generally cover and/orfill in any gap(s) and/or unevenness that may be present at the overlap69′ and may also generally extend a given amount beneath one of thepolymeric sheets 67, 68 and/or atop one of the polymeric sheets 67, 69.The polymeric sheets 67, 68 may also be pressed into the sealing feature70 at the edges 67 c, 68 c to, for example, aid in filling in any gap(s)and/or unevenness at the overlap 69′. The sealing feature 80 in FIGS.12g and 15g may be applied after one polymeric sheet is bonded to thepolymeric core 10 a and before the second polymeric sheet is bonded,such after polymeric sheet 67 is bonded and before polymeric sheet 68 isbonded. The sealing feature 80 may also be bonded to one polymeric sheetand applied with it, such as, for example, by applying the sealingfeature 80 to the edge of polymeric sheet 68 prior to bonding thepolymeric sheet 68 to the polymeric core 10 a and to the polymeric sheet67, which may be bonded before polymeric sheet 68. In another example,the sealing feature 80 may also be applied to one or both of thepolymeric sheets 67, 68 prior to bonding and may thus bond to thepolymeric core 10 a at the same time the polymeric sheets 67, 68 arebonded to the polymeric core 10 a. Suitable sealing features that may beapplied prior to the complete bonding of one film to another and/or tothe core may include a heat activatable composition or tape that isactivatable at the temperature and/or pressure used for bonding thepolymeric sheet 67 or 68 to the core 10 a or to each other. The sealingfeature 80 may also, in still another example, be inserted, injected,pressed-in and/or otherwise interposed between the polymeric sheets 67,68 and/or the polymeric core 10 a after the polymeric sheets 67, 68 arebonded to the polymeric core 10 a. The sealing feature may or may not beactivatable at the temperature and/or pressure of the bonding of thesheet 67 or 68 to the core 10 a, as discussed above.

In another embodiment, as shown in FIGS. 12f-l and 15 h, the sealingfeature 70 is present between the overlap portions 69′ of sheets 67, 68.The sealing feature 70 may be any of the features described above. For adouble-sided adhesive tape, it may generally be applied prior to thebonding of the second sheet 68 to the core and first sheet and theadhesive may be activated by the bonding process. The adhesive may beapplied to the edge of the side of the second tape to be bonded to thecore. For a sealing liquid, it may be applied after the bonding process.

FIGS. 12g and 15g illustrate an embodiment of a load bearing structure10 with a first polymeric sheet 67 and a second polymeric sheet 68 whichmay interface with each other at an overlap 69′. The overlap 69′ maygenerally be formed by one of the edges 67 c, 68 c of the polymericsheets 67, 68, respectively, overlapping the other, as illustrated withedge 68 c lying atop edge 67 c and may result, for example, from asecond polymeric sheet being bonded to the polymeric core 10 a after afirst polymeric sheet. In some embodiments, as illustrated in FIGS. 12gand 15 g, a sealing feature 80 may be utilized to seal the edges of thepolymeric sheets to each other, as illustrated with the edges 67 c, 68 cto each other. The sealing feature 80 may generally cover and/or fill inany gap(s) and/or unevenness that may be present at the overlap 69′ andmay also generally extend a given amount atop the polymeric sheets 67,68. The sealing feature 70 in FIGS. 12g and 15g may be applied after thepolymeric sheets are bonded to the polymeric core 10 a, as the sealingfeature 80 lies atop the overlap 69′. The sealing feature may or may notbe activatable at the temperature and/or pressure of the bonding of thesheet 67 or 68 to the core 10 a, as discussed above. A sealing liquidmay be contained in a bottle or container having a dispensing tip orend. The liquid may be dispensed into the edges where the edges of thethermoplastic sheet meet the core surface or where the edges of the onethermoplastic sheet meet with the edges of a second thermoplastic sheetafter the load bearing structure is made. As noted before, the sealingliquid may be a solvent for the core 10 a and/or the thermoplastic film67 or 68, and may slightly dissolve the material close to the surface ofthe core 10 a or film 67 or 68.

In still other embodiments, as illustrated in FIG. 14 e, a load bearingstructure 10 with polymeric sheets 67, 68 and 68 may cover the top ofthe polymeric core 10 a. The edge 68 c of the polymeric sheet 68 may beoverlapped with the edge of the sheet 67 (not visible here) to form arelatively flush interface, or it may include some gap(s) and/orunevenness which may, for example, result from the manufacturing and/orjoining process of bonding the polymeric sheet 68 to the polymeric sheet67 and the core 10 a. A sealing feature may then be utilized to sealand/or cover the edge 68 c of polymeric sheet 68 and/or extend onto thepolymeric core 10 a, as discussed above. The sealing feature maygenerally cover and/or fill in any gap(s) and/or unevenness that may bepresent at the interface and may also generally extend a given amountonto the polymeric sheet 68 and/or onto the polymeric core 10 a to, forexample, produce a more substantial and/or durable seal. In general, asealing feature that covers the edge of the polymeric sheets whetherthere is an overlap portion 69 a or not, and may be part of thepolymeric core 10 a, may be applied after the polymeric sheets 67, 68 isbonded to the polymeric core 10 a, as the sealing feature lies atop thepolymeric sheet 68. The sealing feature may include any of thosementioned above, for example, a single side coated tape.

Also, in FIG. 14 e, an indent may be present from the bottom edge or thecore 10 a to a portion of the width close to the bottom edge, toaccommodate an edge protector 11, as shown in FIG. 26, or the indent mayextend the entire width to a portion of the top (not shown here) toaccommodate an edge protector 11′, as shown in FIG. 26 a. The indent maynot be visible if the edge protector lies between the core and thepolymeric sheet or sheets.

The sealing liquid may be applied as a sealing feature 70, 80, asdescribed above, and may be applied before or after a polymeric sheet isbonded to the polymeric core. The sealing liquid may also be applied tothe polymeric sheet(s). If the liquid is applied prior to the completionof the bonding of the film 67 or 68 to the core 10 a or to each other,the sealing liquid may be activatable at the temperature and/or pressureof the bonding of the sheet 67 or 68 to the core 10 a, as discussedabove. In some embodiments, as described above, the sealing liquid mayalso be injected beneath the polymeric sheet after completion of thebonding of the sheet 67 or 68 to the core and/or each other and thus maynot need to be activatable at the temperature and/or pressure of thebonding of the sheet 67 or 68 to the core 10 a, as discussed above.FIGS. 13 and 13 a illustrate an example of injecting a sealing liquidunder a polymeric sheet 68 which is already bonded to a polymeric core10 a. FIG. 13 shows an overlap portion between sheets 67, 68 (though notvisible here) and the sealing liquid being injected using a syringe 50beneath the edge 68 c to bond the edge 68 c to the edge of the sheet 67and/or part of polymeric core 10 a. The edge 68 c may then be presseddown, such as by hand or using a pressing tool and/or device, asillustrated in FIG. 13a with a person's finger 90 pressing, to, forexample, reduce any unevenness and/or gaps at the edge 68 c and/or tocreate a more continuous seal.

A sealing chemical composition may be in treated solid or native liquidform, or even in slurries, and may generally be applied to the edges ofthe polymeric sheet before its bonding to the core and its sealingproperty may generally be activated during the bonding process, asdiscussed above. In one embodiment, the chemical composition in liquidform may be encapsulated in a capsule. The capsules do not adhere toeach other so that they come in free flowing forms. However, thecapsules may adsorb or be attracted to the surface of the foam orpolymeric sheet so that they may be applied, for example, by sprinklingonto the surfaces to be sealed prior to the bonding process. Thecomposition may be activated by heat and/or pressure during the bondingprocess of the core to the sheet. In another embodiment, the chemicalcomposition may be applied directly in liquid form, similar to theapplication of the sealing liquid, discussed above, and may or may notneed to be activatable at the temperature and/or pressure of the bondingof the sheet 67 or 68 to the core 10 a, as also discussed above. Forexample, as noted above, the liquid chemical composition may also bemixed with polymeric particles to form slurry. In this embodiment, whenthe polymeric sheets are made from high impact polystyrene, then thepowder is powdered polystyrene. The sealing liquid may be relativelynon-volatile so that the liquid is not substantially evaporated prior tothe bonding process between the sheet with the core and/or sheet. Thechemical sealing composition may also include a self-healing and/orself-repairing composition. This may be desirable as the sealingfeatures may be present in high stress, high damage and/or high wearareas and may increase in effectiveness and/or usage life of the loadbearing structures through the use of self-healing/self-repairingmaterials.

When a sealing tape is used, the tape may include one side having acontact or tacky adhesive and another side with a heat activatableadhesive. The tacky or contact adhesive side may be covered by a linerand the tape may be wound into a roll, as shown in FIG. 14. The roll 63of tape 60 may then be unrolled and the liner 61 removed, eithermanually or using a tape dispenser, to expose the tacky or contactadhesive surface 62, as shown in FIG. 14a and with an example of a tapedispenser 30 in FIG. 14a 1. The tape 60 as shown may be double-coated orsingle-coated tape and may include a liner, may then act as a sealingfeature, such as the sealing features 70, 80, and be applied to the edgeof a polymeric sheet and/or polymeric core, as discussed above and asshown with the tape 60 applied over the edge 67 c of polymeric sheet 67and onto polymeric core 10 a with the liner 61 being removed to exposethe tacky or contact adhesive surface 62 in FIGS. 14b and 14 c. In someembodiments, the tape 60 may be double-sided and in other embodiments,the tape 60 may be one-sided, such as the tape 60 in FIG. 14d and may beapplied over the bonded interface.

The heat activatable adhesive may include hot melt adhesive, a heatcurable adhesive, or a reactive adhesive, on the other side. The heatactivatable adhesive may be selected to be activated at the temperatureduring the bonding process.

In some embodiments, the sealing features 70, 80 may include aself-healing and/or self-repairing composition, as mentioned above. Thismay be desirable as the sealing features 70, 80 may be present in highstress, high damage and/or high wear areas and may increase ineffectiveness and/or usage life of the load bearing structure throughthe use of self-healing/self-repairing materials. For example, somepolymers are capable of healing and/or repairing tears and/or otherdamage by contact repolymerization and/or contact adhesion of adjacentedges of the polymer material. This may include, for example, polymerswhich repolymerize with themselves when exposed to ultraviolet lightand/or other electromagnetic radiation and/or heat. For example,polyurethane-chitosan blended polymers may repolymerize usingultraviolet light to heal tears and/or other discontinuities. Forfurther example, a new class of polymers formed from a condensationreaction between paraformaldehyde and 4,4′-oxydianiline developed by IBMmay also be utilized. As noted above, the self-healing and/orself-repairing composition may be present in any of the various sealingfeatures discussed.

In other embodiments, the sealing features 70, 80 may include a melted,welded, sintered and/or other heat/pressure joining of the materials inthe polymeric sheet(s), such as polymeric sheets 67, 68, and/or thepolymeric core 10 a. For example, ultrasonic welding may be utilized tomelt and/or join the edges of the polymeric sheet(s) together and/or tothe polymeric core 10 a by localized heating. The joining area may alsobe subjected to pressure.

In some embodiments, as illustrated in FIGS. 12h -12 m, the polymericsheets may be folded over each other at an interface. The interface mayfurther be subjected to heat, pressure and/or a vacuum to assist in thejoining the polymeric sheets together at the fold and/or to bond them tothe polymeric core. In one embodiment, a retaining device may beutilized to hold at least one of the polymeric sheets and/or thepolymeric core in place to accomplish the folding and sealing of thepolymeric sheets, as illustrated with retaining device 40 in FIG. 12 h.The polymeric core 10 a may sandwich a first polymeric sheet 67 againstthe retaining device 40. The first polymeric sheet 67 may, for example,be rigid enough at this stage to remain substantially vertical duringthe bonding process until subjected to additional heat, pressure and/ormechanical force to cause it to fold. The first polymeric sheet 67 may,for example, be held in place vertically while it is being bonded to thepolymeric core 10 a (not shown), such that it may be in the propervertical orientation at its edge when it cools and regains rigidity. Insome embodiments, as illustrated in FIG. 12 h, the polymeric core 10 amay also include a chamfered edge 12′, which may, for example, bechamfered at approximately 45 degrees, such as, for further example, toassist in folding of the polymeric sheets. A second polymeric sheet 68may be placed on the polymeric core 10 a and it may also be draped overthe vertical edge of the first polymeric sheet 67 to form a pocket area45, as shown in FIG. 12 i. The second polymeric sheet 68 may also beaffixed to the retaining device 40, such as at edge 68 d, for example,to aid in holding the polymeric sheet 68 in place during folding. Oncethe polymeric sheets 67, 68 are in position, they may be folded overeach other, an example of which as illustrated in FIG. 12 j. Forexample, the end portion 67 d of the polymeric sheet 67 may be foldedtoward the chamfered edge 12′ while a crease 68 e of the polymeric sheet68 may be folded into the pocket area 45. This folding operation may beassisted by heating the polymeric sheets 67, 68, applying pressureand/or mechanical force to the area, and/or applying a vacuum, such asat pocket area 45. Once the folding is completed, as illustrated withthe sandwiched fold of end portion 67 d and crease 68 e in FIG. 12 k,the fold may be sealed using heat and/or pressure, such that, forexample, the polymeric sheets 67, 68 bond together, such as by melting,welding, and/or otherwise adhering to each other. Adhesives, such asheat activated adhesives, may also be present in the area and activatedby heat application to the fold to assist in creating a sealedinterface. The excess material of the polymeric sheet 68 may then betrimmed off, leaving a trimmed edge 68 f, which may be away from theload bearing area, as shown in FIG. 12 l. The finished interface, asillustrated in a close up view in FIG. 12 m, may thus include, forexample, the polymeric sheet 67 sandwiched between 2 layers of polymericsheet 68 at the chamfered edge 12′, with trimmed edge 68 f away from theinterface. The edges may also be bonded with a sealing feature to aid inbonding imperfections, as discussed above.

In some embodiments, the load bearing structure 10 may also includegrooves, détentes, and/or other physical features for denoting where thepolymeric sheet(s) may be trimmed and/or cut, an example of which isillustrated with groove 12 d in FIG. 25. The groove 12 d may be presentaround the entire periphery of the width 12, such that, for example,there may be a physical feature to guide trimming the polymericsheet(s). This may be desirable, for example, where there may be onlyone polymeric sheet bonded to the polymeric core, and the edge of thepolymeric sheet may thus be trimmed short of the load bearing surface 16such that the edge does not cover part of the load bearing surface 16,such that the edge of the polymeric sheet may not catch cargo while itis loaded and/or unloaded.

In some embodiments, as discussed above, edge protecting features,including but not limited to such as shown in FIGS. 26 and 26 a, mayalso be used on the load bearing structures. In one aspect of theinvention, when cargo is loaded onto the load bearing structure, thecargo on its surface may be, for example, held in place by cargo-holdingitems, such as straps, tiedowns, cables, ropes and/or other items. In anexemplary embodiment, the load bearing structure may be reinforced atplaces or continuously with protectors 11 or 11′, such as where thecargo-holding items contact and/or wrap around the load bearingstructure in predetermined areas or anywhere on the load bearingstructure. In some embodiments, the protectors may be edge protectorswhich may be located substantially at the periphery of the load bearingstructure. This may be desirable as, for example, the bottom edge andportion of the width close to the bottom edge of the load bearingstructure generally bear the substantial force of the cargo-holdingitems when used. In one embodiment, the protectors may be presentintermittently at predetermined positions on the load bearing structure10, as shown in FIG. 25 with depressions 12 b and edge protectors 11,where reinforcement may be needed. For example, the protectors maydistribute force and/or pressure from cargo-holding items across alarger area on the load bearing structure and/or reinforce the areaswhere the cargo-holding items are used. The protectors may also, forexample, be harder than the underlying portion of the load bearingstructure which may, for further example, better distribute the forceonto the load bearing structure without significant flexing, deformationor damage. In other embodiments, the protectors may be present on theentire periphery of the load bearing structure rather thanintermittently. Cargo-holding items may be used at these samepredetermined locations or other locations to help keep the cargo inplace. FIG. 24 illustrates an embodiment of a load bearing structure 10which may generally include a top side 16 where cargo may be loaded (notshown), and a width 12 which may be perpendicular or substantiallyperpendicular to the top side 16. In some embodiments, the load bearingstructure 10 may also be utilized with edge protectors. FIG. 24illustrates the load bearing structure 10 which may include multipledepressions 12 b along the width 12 where edge protectors may be placed.In general, the depressions 12 b may be sized to accommodate the edgeprotectors, such as for example, such that the edge protectors lie flushwith the surface of width 12. The depressions 12 b may be placed atregular and/or predetermined intervals about the width 12 and maygenerally be located where cargo-holding items may be in contact withthe load bearing structure 10. In some embodiments, as illustrated inFIG. 24 a, the bottom side of the load bearing structure 10 may includechannels 13 which cargo-holding items may rest in. The depressions 12 bmay thus be located at the ends of the channels 13, as illustrated. Thedepressions 12 b may generally have end edges 12 c, as shown in FIGS.24b and 24 c. In other embodiments, the load bearing structure 10 mayinclude depressions 12 b and the bottom side of the load bearingstructure 10 may not include the channels 13, as illustrated in FIGS.24d and 24 e. The edges 12 c may be somewhat more visible than the restof the depression 12 b and may aid in locating the depression 12 band/or the edge protector when it is in place.

FIG. 25 illustrates an example of a load bearing structure 10 with edgeprotectors 11 in place at the depressions 12 b, as noted above.

As discussed, the end edges 12 c of the depressions 12 b may be presenton the polymeric core 10 a and the edge protectors may be placed in thedepressions 12 b between the end edges 12 c, such that they may beflushed or substantially flushed with the rest of the polymeric core 10a. After covering with the polymeric film or sheet, the protectors mayor may not be easily visible and/or discernible. If the protectorsthemselves are not visible or discernible when in place on the polymericcore 10 a, indicator features may be present, such as, for example, theend edges 12 c may be visible as lines and/or discernible by tactileinspection as a thin indentation.

In some embodiments, the edge protectors may have an L-shapedcross-section, such as illustrated with the L-shaped edge protector 11with an outer surface 11 a which may, for example, contact thecargo-holding item, and an inner surface 11 b which may contact thedepression 12 b, as shown in FIG. 26. The L-shaped edge protector 11 maybe present either intermittently or continuously around the bottom andwidth of the core in a fashion that they envelope a portion of thebottom side near the outer edge to wrap around the edge and extending tocover a portion of the width close to the bottom side, as illustratedpartial cross-sectional view of a load bearing structure 10 in FIG. 25awith the L-shaped edge protector 11 sitting in depression 12 b on thecore 10 a.

In other embodiments, the edge protectors may have a substantiallyC-shaped cross-section, as illustrated with C-shaped edge protector 11′with an outer surface 11 a which may, for example, contact thecargo-holding item, and an inner surface 11 b which may contact thedepression 12 b, as shown in FIG. 26 a. The C-shaped edge protector 11′may be present either intermittently or continuously around the bottom,width and top of the core in a fashion that they envelope a portion ofthe bottom side near the outer edge to wrap around the edge andextending to cover the width and a portion of the top side close to thewidth, as illustrated in the partial cross-sectional view of loadbearing structure 10 with the C-shaped edge protector 11′ wrapped aroundthe width 12 and sitting in depression 12 b in FIG. 25 b. According to afurther embodiment, the edge protectors may come in pairs each having asubstantially L-shaped cross-section, and may be present eitherintermittently or continuously around the bottom, width and top of thecore in a fashion that one of the pair envelopes a portion of the bottomside near the outer edge to wrap around a portion of the edge and theother extending to cover a portion of the width near the top side and aportion of the top side close to the width, which may then appearsimilar to the C-shaped edge protector 11′. The pair may or may not meetwhen placed on the load bearing structure 10. In other embodiments, theload bearing structure 10 may include separate depressions for the upperand lower edges of the width 12, such as shown in the partialcross-sectional view of the load bearing structure 10 in FIG. 25c withupper depression 12 b-l and lower depression 12 b, with an edgeprotector 11-l and 11 sitting in each, respectively, with a separatingportion 12 e of width 12 being exposed between the edge protectors 11,11-l.

In some embodiments, edge protectors may also include guides and/orother features for holding a cargo-holding item, as illustrated in FIGS.27 and 27 a. As illustrated, the edge protector 11″ may include guides11 c which may be utilized to guide and keep in place cargo-holdingitems, such as the strap 9 holding cargo 490 on the load bearingstructure 10 as illustrated in FIG. 27 a. This may be desirable to, forexample, aid in preventing the strap 9 from moving or sliding laterally.The guides 11 c may also protrude and aid in visibility of the edgeprotector 11″ such that the cargo-holding items may be positioned overthem.

In some embodiments, the protector(s) may be present on the core priorto the covering of the core by the polymeric sheet, as discussed above.In one aspect, the core may be indented to accommodate the protectors sothat the protectors are flushed with the core so that the sheet maycover the core with protectors as if the protectors are not present, asdiscussed and illustrated above with FIGS. 24-26 a. In another aspect,the core may be indented but not sufficiently to accommodate the entirethickness of the protectors so that after covering with the sheet, theremay be a slight bulge where the protectors are present, which can beseen with edge protectors 11″ protruding as a bulge in FIGS. 27 and 27a. In another embodiment, the protectors may be added after the core iscovered with the polymeric sheet or sheets.

The protectors may be constructed from any polymeric or metallicmaterials, or combinations thereof, that may be easily molded or castinto the desired shape and are rigid or substantially rigid or possesssufficient reinforcement for the edges. In one embodiment, when theprotectors are present on the core prior to the covering of the core bythe polymeric sheet or sheets, the protectors may be made of same ormaterial having similar bonding properties as the sheet to facilitatethe bonding of the protector both to the sheet and/or core at thebonding temperature of the sheet to the core. This may be furtherdesirable as the load bearing structure may be more easily and/orreadily recycled when composed of substantially a single material. Whenthe edge protectors are present on the core, the polymeric sheet orsheets may or may not be combined or bonded to the edge protectors ifthe edge protectors are not made with similar material or the edgeprotectors are not combined or bonded to the polymeric sheet or sheets,the outer edges of the sheet may be bonded to the edge protector by thesealing feature.

In another embodiment, when the protectors are added to the load bearingstructure after bonding of the sheet or sheets to the core, any materialmay be used for the protectors.

In addition to the same or similar materials to the polymeric sheets,suitable materials for the edge protectors, especially those that arepresent on the load bearing structure after the bonding of the core tothe sheet or sheets, may include any metallic and polymeric material, aslong as such material may be fabricated into the resulting rigid orsubstantially rigid parts. Examples of appropriate materials mayinclude, but are not limited to, for example, a polymer that may bemolded, thermoformed or cast. Suitable polymers include polyethylene;polypropylene; polybutylene; polystyrene; polyester;polytetrafluoroethylene (PTFE); acrylic polymers; polyvinylchloride;Acetal polymers such as polyoxymethylene or Delrin (available fromDuPont Company); natural or synthetic rubber; polyamide, or other hightemperature polymers such as polyetherimide like ULTEM®, a polymericalloy such as Xenoy® resin, which is a composite of polycarbonate andpolybutyleneterephthalate, Lexan® plastic, which is a copolymer ofpolycarbonate and isophthalate terephthalate resorcinol resin (allavailable from GE Plastics); liquid crystal polymers, such as anaromatic polyester or an aromatic polyester amide containing, as aconstituent, at least one compound selected from the group consisting ofan aromatic hydroxycarboxylic acid (such as hydroxybenzoate (rigidmonomer), hydroxynaphthoate (flexible monomer), an aromatic hydroxyamineand an aromatic diamine, (exemplified in U.S. Pat. Nos. 6,242,063,6,274,242, 6,643,552 and 6,797,198, the contents of which areincorporated herein by reference), polyesterimide anhydrides withterminal anhydride group or lateral anhydrides (exemplified in U.S. Pat.No. 6,730,377, the content of which is incorporated herein byreference)or combinations thereof. Some of these materials arerecyclable or be made to be recyclable. Compostable or biodegradablematerials may also be used and may include any biodegradable orbiocompostable polyesters such as a polylactic acid resin (comprisingL-lactic acid and D-lactic acid) and polyglycolic acid (PGA),polyhydroxyvalerate/hydroxybutyrate resin (PHBV) (copolymer of 3-hydroxybutyric acid and 3-hydroxy pentanoic acid (3-hydroxy valeric acid) andpolyhydroxyalkanoate (PHA) copolymers, and polyester/urethane resin.Some non-compostable or non-biodegradable materials may also be madecompostable or biodegradable by the addition of certain additives, forexample, any oxo-biodegradable additive such as D2W™ supplied by(Symphony Environmental, Borehamwood, United Kingdom) and TDPA®manufactured by EPI Environmental Products Inc. Vancouver, BritishColumbia, Canada.

In addition, any polymeric composite such as engineering prepregs orcomposites, which are polymers filled with pigments, carbon particles,silica, glass fibers, or mixtures thereof may also be used. For example,a blend of polycarbonate and ABS (Acrylonitrile Butadiene Styrene) maybe used. For further example, carbon-fiber and/or glass-fiber reinforcedplastic may also be used.

Useful metals or metallic materials may include metal and metal alloyssuch as aluminum, steel, stainless steel, nickel titanium alloys and soon.

To aid to keep the protectors on the core prior to bonding and duringthe bonding process, an adhesive or double-coated adhesive tape may beused. This may be desirable as, for example, the protectors may notsignificantly adhere and/or grip the load bearing structure prior to thebonding process. Examples of the adhesive may include pressure sensitiveadhesive, for example, a hot melt pressure sensitive adhesive or anon-hot melt pressure sensitive adhesive. Examples of double-coated tapemay include double coated pressure sensitive adhesive tape, for example,a double-coated hot pressure sensitive tape or a double-coated non-hotmelt pressure sensitive tape. The thickness of the adhesive or tape maybe thin so that it does not contribute to the thickness of the edgeprotectors substantially and/or to prevent the edge protectors fromprotruding significantly from the surface of the load bearing structure.In some embodiments, the adhesive or tape may be substantially meltedduring the bonding process. The amount of adhesive or tape may also beminimal as to not contribute significantly to the overall materialcomposition of the load bearing structure, as this may be furtherdesirable as the load bearing structure may be more easily and/orreadily recycled when composed of substantially a single material.

In other embodiments, the protectors may use friction fits, roughenedand/or textured contact surfaces and/or other mechanical means forattaching and/or holding them in place on the load bearing structure.

To keep the edge protectors firmly in place when the protectors arepresent after the bonding process, a structure adhesive may be used,such as those used in edge sealing described above or later, so that theedge protectors do not detach or move about during and after strappingto keep the cargo in place.

The protectors may have any thickness, as long as they provide theneeded reinforcement for the edges. Some materials possess higherrigidity than others and therefore thinner protectors may havesufficient rigidity. For those that are more flexible, thickercomponents may be needed to provide sufficient rigidity.

The edge protectors may be manufactured by molding or casting. In oneembodiment, the edge protectors may be made in bulk and then cut tosize. In another embodiment, the edge protectors may be individuallymade to size. The substantially L-shaped edge protectors 11 and thesubstantially C-shaped edge protectors 11′ may also be desirable as thecontinuous cross-sectional shape may allow them to formed by extrusionas a continuous length which may be cut to size.

The loading bearing structure of the present invention, which may be adunnage platform or container, may have anti-microbial properties.Antimicrobial means an agent that is active against one or moreorganisms including bacteria, viruses, fungi, protists, helminths andinsect larvae. Foreign hosts mean a microbe, pathogen or organisms thatcan be transported on a surface of a load bearing structure. Theantimicrobial agent may be in powder form or in liquid form.

In one exemplary embodiment, an antimicrobial agent capable ofeliminating, preventing, retarding or minimizing the growth of microbesmay be present on the exposed surfaces, for example, top side 16, thewidth 12 a and/or the bottom side 18 of loading bearing structure 10, asshown in FIG. 1.

In any of the embodiments, the antimicrobial properties may be generatedfrom materials including chemical anti-microbial materials or compoundsthat are capable of being substantially permanently bonded, at least fora period such as the useful life of the load bearing structures, eitherwhen at least one antimicrobial agent is added to the material used formaking the polymeric layer, for example, a sheet mentioned above, orwhen at least one antimicrobial agent having some surface activity iscoated onto the exposed surface of the polymeric layer, for example,sheet mentioned above; or maintain their anti-microbial effects when atleast one antimicrobial agent is coated with the aid of coating agents,onto the exposed surface of the polymeric layer, for example, sheetmentioned above. In one example, the chemicals may be deposited on thesurface of the loading bearing structures by covalent linkage.

When the antimicrobial agent or agents are incorporated in the materialused in making the polymeric layer, for example, a sheet, the agent oragents maybe dispersed directly into the material, or with the aid of anappropriate carrier, for example, a binding agent, a solvent, or asuitable polymer mixing aid. These carriers may also be useful forcoating aids mentioned above. Effective binding agents are those that donot interfere with the antimicrobial activities of the antimicrobialagent. In one embodiment, when the anti-microbial agent is incorporatedinto the material used for making the polymeric layer, for example, asheet mentioned above, the antimicrobial agent maybe master batch in thematerial, or an appropriate carrier at a higher concentration prior toadding to the material for making the polymeric layer, for example, asheet in desired proportions. In another embodiment, the antimicrobialagent may be added directly to the material for making the polymericlayer, for example, a sheet without the intermediate step.

In other embodiments, the antimicrobial agents, either in coatings orincorporated into the materials for making the polymeric layer, mayinclude chemical antimicrobial materials or compounds that may bedeposited in a non-permanent manner such that they may slowly dissolve,slowly leach or otherwise deliver antimicrobial substances during use.The material may be adequately incorporated, though temporarily and/orin sufficient amounts to last at least for a period such as the usefullife of the load bearing structures, either when at least oneantimicrobial agent is added to the material used for making thepolymeric layer mentioned above, or when at least one antimicrobialagent is coated onto the exposed surface of polymeric layer, forexample, the sheet mentioned above; or maintain their anti-microbialeffects when at least one antimicrobial agent is coated with the aid ofcoating agents, onto the exposed surface of the polymeric layer, forexample, a sheet mentioned above. The suitable agent or agents are thosethat tend to slowly migrate or non-leaching, as defined herein, to thesurfaces to provide antimicrobial properties to the surfaces.

In still other embodiments, the antimicrobial agent either in coatingsor incorporated into the material used for making the polymeric layer,may include sources of anti-microbial agents which may leach and/orrelease agents in a moist environment or upon contact with moisture.These sources may be incorporated into the substrate materials used formanufacturing the polymeric layer, for example, sheet mentioned above.Incorporation of these sources may be especially suited to polymericsubstrates.

Chemical antimicrobial materials or compounds may include a variety ofsubstances including, but not limited to antibiotics, antimycotics,general antimicrobial agents, quaternary ammonium cations, a source ofmetal ions such as metal ion generating materials, triclosan,chlorhexidine or any other materials capable of generating anantimicrobial effect, and/or any other appropriate compound or mixturesthereof.

In yet further embodiments, antimicrobial activity may be achieved byutilizing the antimicrobial properties of various metals, especiallytransition metals which have little to no effect on humans. Examples mayinclude sources of free silver ions, which are noted for theirantimicrobial effects and few biological effects on humans. Metal ionantimicrobial activity may be created by a variety of methods that mayinclude, for example, mixing a source of a metal ion with the polymericlayer, for example, sheet material during manufacture, coating thesurface by methods such as plasma deposition, loosely complexing themetal ion source by disrupting the surface of the polymeric layer, forexample, coating or sheet to form affinity or binding sites by methodssuch as etching or coronal discharge, and depositing a metal onto thesurface by means such as electroplating, photoreduction andprecipitation. The coated surface may then slowly release free metalions during use that may produce an antimicrobial effect.

In some embodiments, the source of metal ions may be an ion exchangeresin. Ion exchange resins are substances that carry ions in bindingsites on the surfaces of the material. Ion exchange resins may beimpregnated with particular ion species for which it has a givenaffinity. The ion exchange resin may be placed in an environmentcontaining different ion species for which it has a generally higheraffinity, causing the impregnated ions to leach into the environment,being replaced by the ion species originally present in the environment.

In one embodiment, the polymeric layer may include an ion exchange resincontaining a metal ion source, such as, for example, silver. Ionexchange resins containing metal ion sources may include, for example,Alphasan® (Milliken Chemical), which is a zirconium phosphate-basedceramic ion exchange resin containing silver. An ion exchange resin maybe coated onto the polymeric layer or it may be incorporated into thematerial of the sheet or sprayed coating, as discussed above.

In some embodiments, a layer of substantially non-permanent coatingincluding an anti-microbial compound may be present on top of a layer ofa substantially permanent coating including an anti-microbial compound.

The substantially permanent anti-microbial coating may be, for example,substantially flexible so that the coating substantially covers theworking surfaces of the loading bearing structure during use even if thestructure flexes. If the anti-microbial compound is not capable offorming a substantially flexible coating by itself, then a binding agentcapable of forming a substantially flexible coating may be used to aidin the flexibility of the resulting coating.

The details of antimicrobial coatings and agents can be found in U.S.patent application Ser. No. 13/549,474, entitled “A LOAD BEARINGSTRUCTURE HAVING ANTIMICROBIAL PROPERTIES”, the contents of which arehereby incorporated by reference in their entirety.

The load bearing structure may also include a plurality of bridges,runners, wear resistant members and/or connectors that may be affixed tothe second side of at least some of the extensions or supports 20-28 ofall of the embodiments of loading bearing structures described herein.Wear resistant members may generally be attached to the bottom of someof the plurality of supports so that they may protrude from the bottomof the supports and aid in the wear of the supports. Details of the wearresistant members may be found in U.S. Pat. Nos. 7,908,979, and5,868,080, the contents of all of which are hereby incorporated byreference.

These wear resistant members may be similar to bridges or runners thatextend between adjacent extensions or supports. In some embodiments,only one of these members may be present. In other embodiments, two ofthese may be arranged in the shape of a cross. In further embodiments,one of each may be attached to each pair of adjacent extensions orsupports around the peripheral of the load bearing structure. In stillother embodiments, they may be attached to every pair of extensions orsupports of the load bearing structure.

Runners, bridges and/or other connectors may also be included, such as,for example, connecting multiple supports, which may generally increasethe strength and/or rigidity of the base. FIG. 21a illustrates anexample of crossed runners 906 connecting multiple extensions orsupports 904. FIG. 21 illustrates an example of runners 926 connectingsets of three extensions or supports 924 along two edges. FIG. 21dillustrates an example of runners 916 connecting three sets ofextensions or supports 914 in a parallel arrangement. In general, anydesired combination of extensions or supports may be connected byrunners or bridges. The runners or bridges may be manufactured from anysuitable material. For example, the bridges may be constructed fromwood, metal and/or various plastics materials, including those mentionedabove for manufacturing the film covering, including polyolefins,polyesters, lead free PVC, etc. In some embodiments, the runners orbridges are manufactured from HIPS (high impact polystyrene) using anextrusion forming process. Further, the bridges may be configured sothat they each span two or more supports of a row and may be affixed tothe ends of said supports so that they interconnect. For example, thebridges may be affixed using a suitable adhesive.

As mentioned above, the runners or bridges may be attached to the bottomof the supports, either flushed with the bottom portions of thesupports, for example, attached within an indented portion formed in thebottom of the supports, such as shown in FIGS. 21c and 21 d, orprotruded from the bottom portions of the supports, such as shown inFIG. 21 a, and thus improves the wear and tear of the supports. Inaddition, the bottom of the runners or bridges may also be roughened toimprove slip resistance of the base.

For light weight load bearing structures, the core 10 a is generallymade of foam, for example, a closed cell foam core 10 a such as anexpanded polystyrene core 10 a with a region proximal to its surfacethat is combined with a polymeric layer, for example, high impactpolymeric sheet 67, for example, a polystyrene sheet, by heat and/orpressure.

The foam core 10 a may be made from already manufactured bulk form, suchas expanded polystyrene foam which may be cut to the desired shape andsize. The foam density may also be varied, depending on the degree ofexpansion of the beads used to make the foam. The foam density may alsodecide the suitable load or cargo to be loaded.

The foam core in general by itself, unless it is of higher density, forexample, the beads are not highly expanded, may not have sufficientstructural strength to be usable as a load bearing platform. A dunnageplatform with sufficient strength may be formed by combining the core 10a with a high impact polymeric sheet 67, for example, a polystyreneSheet. In one embodiment, the sheet 67 may include an antimicrobialagent, which may be added to the material used for making the sheet 67.The antimicrobial agent may be in powder form or in liquid form. Inanother embodiment, at least one antimicrobial agent may be coated ontothe exposed surface 16 of the sheet 67. The antimicrobial agent may bein powder form or in liquid form. When the agent is coated, the coatingmay take place before the sheet 67 is combined with the core 10 a orafter the load bearing structure 10 is made.

The combination may be effected by heat and/or pressure. In one specificexample of a load bearing structure, a combination process may causeportions of an expanded polystyrene core 10 a proximal to the bottomside 18 a to be combined with the high impact polystyrene sheet 67 toform a strengthened polystyrene by heat and pressure. Additionally, aportion of the expanded polystyrene that is proximal to the edge 12 aand in a proximal relationship to the bottom side 18 a may be combinedwith the high impact polystyrene by heat and pressure to form thestrengthened polystyrene, if desired. Details of this combinationprocess may be found in U.S. Pat. No. 6,786,992, the content of which isincorporated herein by reference in its entirety.

Another specific example of a load bearing structure 10 may be asdisclosed in U.S. Pat. No. 7,908,979, WO04041516 and U.S. Pat. No.7,413,698, the contents of all of which are incorporated herein byreference in their entirety.

In another exemplary embodiment, any of the load bearing structuresdescribed above, as shown for example, in FIGS. 1, 12, 12 a-f, includingthose having an antimicrobial coating capable of eliminating,preventing, retarding or minimizing the growth of microbes may bepresent in the materials making up the polymeric layer, for example,sheets or coated on the exposed surface or surfaces may be assembledinto a container, with the load bearing structures discussed aboveforming any of the walls, top and base components of the container, asshown in FIG. 5-FIG. 7, and FIGS. 8, 8A-FIG. 8E the base having aplurality of supports extending therefrom the underside of the core 10 aThe walls and top may or may not include supports.

The containers may have a base in the structure of, for example, FIG. 4,which may also be made either by combining the core 10 a with apolymeric sheet 67, as noted above for FIG. 1, In FIG. 3, a line drawingof a loaded cargo carrier dunnage platform with a half enclosure 380positioned on the cargo carrier dunnage platform loaded with cargo 490,according to an embodiment of the invention. Referring again to FIG. 4,the cargo carrier dunnage platform 10 may be useful as a base of thecontainer of FIG. 3, with a top surface 115 and edges 110 is shown. Inthis embodiment, the dunnage platform 10 a shown has six (6) pockets 125and two (2) grooves or recesses 130 penetrating the top surface 115,each of which may extend into the core 10 a (not shown) of the dunnageplatform 10. In an embodiment of the invention, the pockets 125 may beused to locate phase change materials. In an embodiment of theinvention, the grooves or recesses 130 are used to locate one or moreenclosures. FIG. 4(A) shows the container of the embodiment of FIG. 3,devoid of cargo.

FIG. 3A shows the cargo carrier dunnage platform with phase changematerial containers or pouches 125 a positioned in pockets 125 and ahalf enclosure positioned on the cargo carrier dunnage platform,according to an embodiment of the invention. These containers or pouchesare shown here in substantially rectangular form, but they may be inother forms.

In another embodiment, as shown in FIG. 9, the base may also be such asshown in FIG. 1, but again with groove 130.

In one exemplary embodiment, a container 100 (FIG. 5) or 300 (FIG. 6)may be a knock-down or collapsible shipping container made up of aplurality of surfaces including a base 106 or 306, four walls 101 (103)or 301 (303) and a top panel 404 (as shown in FIG. 7), each being madefrom a light weight polymeric core bonded or laminated with athermoplastic sheet. In one embodiment of the invention structural metalmesh can be inserted into the core 101 a (not shown) to resist piercingof any of the surfaces. In another embodiment of the invention, thewalls may be held together with clasps 450, as shown in FIG. 7. Theshipping and/or storage container 400 is modular, lightweight, and maybe thermally insulating, and/or tamper proof, and provides a sanitarysurface coating and thermal capacity for transportation of foodstuffsand other valuable products. Upon delivery and unloading, the walls andtop of the container can be disassembled and stacked on the dunnage baseto reduce the volume of the container for storage or further shipment.The detail of this container is as described in U.S. Pat. No. 7,963,397,the content of which is hereby incorporated by reference in itsentirety.

In another exemplary embodiment of the invention, a knock down orcollapsible container for storage and/or shipping having a base, fourwalls extending therefrom and a top panel to form an enclosure therein,each of which having an inside surface, an outside surface, a widthjoining the inside and outside surfaces, and four inside edges and fouroutside edges. The container when collapsed or knock-down, has a footprint not larger than the foot print of the largest individualcomponent, as shown in FIG. 8, FIG. 8A-FIG. 8E. In an embodiment of theinvention, each of the base, four walls and top includes a continuousfeature extending substantially along a surface no more thanapproximately 80 percent, of any of the four inside edges of the walls,base and top of each of the components of the container, the features onadjacent members are of opposite interlocking characteristics, as shownin FIG. 8, FIG. 8A-FIG. 8E. That is, if an edge has a groove, the grooveis less than 80 percent of the length of the edge.

In an alternative embodiment of the invention, each of the base, fourwalls and top includes a continuous feature extending substantiallyalong a surface no more than approximately 90 percent of any of the fourinside edges of the walls, base and top of each of the components of thecontainer, the features on adjacent members are of opposite interlockingcharacteristics. That is, if an edge has a groove, the groove is lessthan 90 percent of the length of the edge.

Interlocking features characteristics may also be defined as adepression in a wall of a container corresponding to a protrusion in thecargo such that the container ‘mates’ with the cargo without requiring afastener. Interlocking characteristics may include respective depressionand protrusion features on adjacent connecting components. For example,when the features along one side have a receiving characteristic, thefeatures on the adjacent member are of a protruding characteristic sothat the interlocking features mate to form a container without any aidfrom additional clips or fasteners. The phrase ‘without requiring afastener’ means that the interlocking features are interlocked withoutthe aid of any component that is not the base, the four walls or thetop. Additional securing devices may be employed to insure furtherintegrity of the container, if needed, and such additional securingdevices may include straps and/or shrink wrap packaging. In oneembodiment, each of the walls, top and base of the container may be madeof a light weight core substantially covered with a polymeric layer, forexample, high impact sheet, having antimicrobial properties or having atleast one antimicrobial agents incorporated therein or thereon, on atleast one of its surfaces to form a load bearing structure having awidth as noted above. In another embodiment, a structural metal mesh maybe inserted into the core to resist piercing of the surface, and each ofthe walls, top and base of the container may be made of a light weightcore substantially covered with a polymeric layer, for example, highimpact sheet, with or without antimicrobial properties or having atleast one antimicrobial agents incorporated therein or thereon, on atleast one of its surfaces to form a load bearing structure having awidth as noted above. FIG. 8 illustrates a perspective view of anassembled container 800 which may generally include a base 812, sidepieces 801, 802, 803 and 804, and a top 816. In general, the container800 may be assembled into the form illustrated in FIG. 8 without the useof adhesives, fasteners and/or other assembly aids and may substantiallyassemble in a predetermined fashion and retain the illustrated form. Inone embodiment, as shown in FIG. 8A, the base 812 may generally berectangular and may include a plurality of channels or grooves 831, 832,833 and 834, each adjacent to an edge of the base 812. The grooves 831,832, 833 and 834 may each terminate at a corner which is substantiallyopen to the edge, as shown with corners 812 a, b, c and d, such that thegrooves are open at least one end to insert a side piece. The corners812 a, b, c and d may also include a closed edge which may thus act as astop such that, for example, a side piece(s) may abut against the closededge of the corner and be substantially retained and prevented fromadvancing beyond the corner. As illustrated in FIG. 8B, a side piece,such as side piece 801, may include a corresponding ridge 841, which mayslide into and be retained in a corresponding groove, such as groove 831as illustrated. The side pieces, such as illustrated with side piece801, may further include a ridge 841 a opposite ridge 841 which maycorrespond and be retained in a corresponding groove of the top 816.

In general, the side pieces 801, 802, 803 and 804 may include edgesorthogonal to ridges which correspond to the grooves of the top 816 andbase 812, as illustrated in the top view of the container 800 in FIG.8C. In general, the orthogonal edges may mate to each other withinterlocking connections, as illustrated with connections 853, 854 and855. In general, to assemble the container 800, for example, the sidepiece 804 may be inserted into the groove 834, followed by side piece803 in groove 833, side piece 802 in groove 832 and then side piece 801in groove 831. Side pieces 801 and 802 may include a non-interlockingjunction, as illustrated with abutting edges 851 and 852, such that sidepiece 801 may be inserted without interference from a protruding piece.The top 816 as illustrated in FIG. 8D, which may include grooves 833 a,833 b, 833 c and 833 d, which may correspond to ridges 842 a, 842 b, 842c and 842 d of the side pieces, respectively, may then be placed suchthat the corresponding ridges fit into the grooves of the top 816,closing the container 800. The top 816 may also, for example, be placedbefore all of the side pieces are placed, such as illustrated in FIG.8E. The side pieces, such as side piece 801 as illustrated in FIG. 8E,may also include handling features, such as the handle depressions 801d, such that the side pieces may be manipulated with greater ease.

These embodiments of the container are described in detail in U.S.patent application Ser. Nos. 13/549,472, and 14/158,488, both entitled“Cargo Container for Storing and Transporting Cargo”, the contents ofall of which are hereby incorporated by reference in their entirety.

In a further exemplary embodiment, the container includes two identicalsubstantially L-shaped cross-section halves, 380, each having at leasttwo walls and a base or top component, each of the components havingcorresponding or complementary interlocking features to be matedtogether to form a container having an enclosure therein, as shown inFIG. 4A. In other embodiments, the base may not have pockets. Each ofthe halves having an inner surface and an outer surface joined by awidth. The footprint of the knock-down or collapsed container is notlarger than the substantially L-shaped cross-section halves. In oneembodiment, each half is made of an inner light weight core covered byat least one layer of strengthened coating. In another embodiment, astructural metal mesh may be inserted into the core to resist piercingof the surface. In one aspect, the container may have thermal insulatingproperty for minimizing exposure of cargo to cold temperatures. Inanother aspect, the container may have thermal insulating property forminimizing exposure of cargo to high temperatures. In a further aspect,the container may have a combination of any of the properties describedin the previous aspects. According to one embodiment, the container mayinclude an enclosure having one undivided internal compartment.According to another embodiment, the container may include an enclosurehaving more than one internal compartments. These embodiments are alsodisclosed in U.S. patent application Ser. Nos. 13/549,472, and14/158,488, both entitled “Cargo Container for Storing and TransportingCargo”, and U.S. patent application Ser. No. 13/254,127, entitled“Climate control Cargo Container for Storing, Transporting andPreserving Cargo”, the contents of which are incorporated herein byreference in their entirety.

As noted above, the containers include those as described in FIGS. 5, 6and 7, (and also disclosed in U.S. Pat. No. 8,672,137, the contents ofwhich is incorporated herein in its entirely,) at least one of theexposed surfaces thereof may also have antimicrobial properties andpockets may be added for containing phase change materials.

According to one embodiment, the container may include an enclosurehaving one undivided internal compartment, as shown in FIG. 3, FIG. 8Cor FIG. 10. According to another embodiment, the container may includean enclosure having more than one internal compartments, notspecifically shown. In one aspect, the interior may have dividers moldedinto the side of the component structures (not specifically shown). Inanother aspect, the dividers may be added to the container to formseparate compartments. Features 612 or 622, as shown in FIG. 10, FIG.10A and FIG. 11A, may be present or molded into the components of thecontainer to allow for placement of dividers to adjust the size of thecompartments.

FIG. 10, FIG. 10A and FIG. 11A show embodiments of a substantiallyL-shaped cross-section half of a container 600, having channel orgroove, 130, molded or formed on the various sides. Slots 612 or 622,are molded or formed on the interior of all side, base or topcomponents, 610 or 620 of FIG. 10, 10 a or 11 a, for attaching dividers(not shown) to create various compartments inside the enclosure, or forattaching shaped features 700 for resting cargo, as shown in FIG. 11A.In one embodiment, the slots 612 or 622, may be formed or molded infixed distance apart, as shown in FIG. 10, FIG. 10A and FIG. 11A so thatsame size or multiples of one size compartments may be formed. Inanother embodiment, they may be formed or molded in varied distanceapart (not specifically shown), so that different size compartments maybe formed which may or may not be multiples of one size. In one aspect,the slots are formed at corresponding positions on the inside surfacesof the side, top or bottom components to form compartments that areeither substantially parallel to the horizontal or vertical. In anotheraspect, the slots are formed at an angle with respect to the horizontalor vertical.

According to one embodiment, features 700 may be formed or molded intothe components of the container for placement of cargo or placement ofother components for more secure location of cargo.

FIG. 11 shows a closed container 600 by mating two substantiallyL-shaped cross-section halves, such as that shown in FIG. 10 or FIG.11A.

The containers may be made of the size and shape to accommodate thecargo, or the cargo may be contained in its own packaging and theninserted into the container 380 or 600.

In some embodiments, the container having an enclosure may also be madeup of a knock down or collapsible container 200 for storage and/orshipping, as illustrated in FIG. 16, having a base, four walls extendingtherefrom and a top panel to form an enclosure therein, where the fourwalls are substantially similar in shape and feature identicalinterlocking features such that the container 200 may have a minimum ofthree different components: a top panel, a base and a wall panel. Theidentical interlocking features on the wall panels may also generallyaid in forming a rigid, resilient and easy to assemble/disassemblecontainer 200.

FIG. 16 illustrates a perspective view of a container 200 which mayinclude a top panel 210, four wall panels 220 and a base 230. The wallpanels 220 may generally join to each other at side interfaces 204 toform a substantially rectangular enclosure with a space 201 as shown inFIG. 16 a, which in turn may join with the base 230 at base interface206 and with the top panel 210 at top interface 202.

In general, the base 230, as illustrated in FIGS. 17 and 17 a, mayinclude a main platform 232 on which cargo and/or other material mayrest when the container 200 is assembled. As noted above, the mainplatform portions of all the components define the inner space of thecontainer 200 when assembled. The base 230 may also generally include aplurality of supports, such as extensions or supports 238, which mayextend from the bottom surface 231, as shown in FIG. 17 a. At the baseinterface 206 with the wall panels 220, the base 230 may generallyinclude an interface feature, such as the circumferential groove 236between the main platform 232 and an outer circumferential ring or edgeportion 234, as shown in FIG. 17. In general, a portion of the wallpanels 220 may interface with the base 230 by insertion into thecircumferential groove 236. A portion of the wall panels 220 may alsorest on the top surface 235 of the circumferential ring 234, such that,for example, the wall panels 220 and the base 230 may interface with aminimal gap or space at base interface 206. The base 230 may alsofeature rounded, chamfered and/or otherwise smooth shaped edges suchthat sharp and/or pointed portions of the container 200 may beminimized, such as with chamfered edge 237 and rounded corners 239 ofthe circumferential ring 234, and with rounded corners 233 of the mainplatform 232, as illustrated in FIG. 17.

In general, the top panel 210, as illustrated in FIGS. 19 and 19 a, mayinclude a main platform portion 212 which may form the roof when thecontainer 200 is assembled, and an outer surface 211. At the topinterface 202 with the wall panels 220, the top panel 210 may generallyinclude an interface feature, such as the circumferential groove 216between the inner main platform portion 212 and an outer circumferentialring 214, as shown in FIG. 19 a. In general, a portion of the wallpanels 220 may interface with the top panel 210 by insertion into thecircumferential groove 216. A portion of the wall panels 220 may alsorest on the bottom surface 215 of the circumferential ring 214, suchthat, for example, the wall panels 220 and the top panel 210 mayinterface with a minimal gap or space at base interface 202. The toppanel 210 may also feature rounded, chamfered and/or otherwise shapededges such that sharp and/or pointed portions of the container 200 maybe minimized, such as with chamfered edge 217 and rounded corners 219 ofthe circumferential ring 234, and with rounded corners 213 of the mainplatform portion 212, as illustrated in FIGS. 19 and 19 a.

Each of the wall panels 220 may generally include a rectangular panel222 with four edges with interfacing features. In some embodiments,three of the four edges may be formed as stepped edges with a portion ofthe overall thickness of the rectangular panel 222 extending outward,such as to form a partially circumferential step, such as illustrated inFIGS. 18 and 18 e with the stepped edges 226 a, 226 b, and 226 c formingstep 226. The fourth edge may be formed as a wrap-around extension, suchas illustrated with the extension 224 with a portion of the overallthickness of the rectangular panel 222 in FIGS. 18 and 18 a, thatextends out from the edge 223 and wraps at a substantially 90° angle tothe plane of the rectangular panel 222 towards the inner surface 228 ofthe rectangular panel 222, which may generally form a channel or groovebetween the wrap-around portion of the extension 224 and the unextendededge 223 a of the rectangular panel 222, such as the groove 225 asillustrated in FIGS. 18 and 18 a.

The stepped edges 226 a, 226 b, and 226 c may generally be shaped to fitinto grooves of other components of the container 200, such as, forexample, the edge 226 a fitting into circumferential groove 216 of toppanel 210 shown in FIG. 18 b, edge 226 b fitting into the groove 225 ofanother wall panel 220 shown in FIG. 18 c, and edge 226 c fitting intothe circumferential groove 236 of base 230 shown in FIG. 18 d, which maygenerally form substantially continuous interfaces between thecomponents at top interface 202, side interfaces 204 and base interface206, with minimal space and/or gaps between the components. Theinterfacing grooves, extensions and/or corner interfaces may alsogenerally act as tongue and groove interfaces, and may thus providerigid and/or largely self-supporting connections between the componentswhich may require minimal if any reinforcement when assembled. Theinterfaces may also generally resist loads in all directions.

In other embodiments, the wall panels 220, as illustrated in FIGS. 18and 18 a, may also include an outer panel 222 joined and/or formed as aunitary component with an inner panel 226. The outer panel 222 maygenerally include an interface feature on one side, such as the cornerinterface 234, which may generally extend past the edge of the innerpanel 226, as illustrated. In some embodiments, the corner interface 234may generally include a substantially L-cross section such that it maysubstantially span a 90° corner for interfacing with another wall panel220. The L-cross section of the corner interface 234 may generally forma groove 225 between the corner interface 234 and the inner panel 226.

The inner panel 226 may generally include interfaces which extend pastthe edges of the outer panel 222 except on the edge with the cornerinterface 234, such as with extensions 226 a, 226 b and 226 c, asillustrated. The extensions 226 a, 226 b and 226 c may generally beshaped to fit into grooves of other components of the container 200,such as, for example, the extension 226 a fitting into circumferentialgroove 216 of top panel 210 shown in FIG. 18 b, extension 226 b fittinginto the groove 225 of another wall panel 220 shown in FIG. 18 c, andextension 226 c fitting into the circumferential groove 236 of base 230shown in FIG. 18 d, which may generally form substantially continuousinterfaces between the components at top interface 202, side interfaces204 and base interface 206, with minimal space and/or gaps between thecomponents. The interfacing grooves, extensions and/or corner interfacesmay also generally act as tongue and groove interfaces, and may thusprovide rigid and/or largely self-supporting connections between thecomponents which may require minimal if any reinforcement whenassembled. The interfaces may also generally resist loads in alldirections.

In some embodiments, the wall panels 220 may be identical and may form acontainer with a square cross-section. This may be desirable as thetotal number of different components required is three (top panels,bases and wall panels). In other embodiments, wall panels 220 ofdifferent dimensions may be used, for example, with two wall panels ofone length and two wall panels of another length, such that thecontainer cross-section will be a rectangle. In general, the dimensionsof the top panel 210 and the base 230 may determine the required type ofwall panel 220 to be used.

In general, the container 200 may be assembled by interfacing the wallpanels 220 with the base 230 and capping with the top panel 210, asillustrated in FIG. 20. Since all of the corner interfaces 224 and theextensions 226 a, 226 b and 226 c project from a single plane, the wallpanels 220 may be inserted into the base 230 one at a time, such as by asingle assembler, and the wall panels 220 may interface with each otherand the base 230 through purely vertical translation, as illustrated inFIG. 20, which may be desirable to reduce awkward and/or difficultassembly steps.

The base of a container may generally include a plurality of supports,such as extensions or supports, which may take various forms or shapes,such as illustrated with the extensions or supports of bases 900, 910920 and 930 in FIGS. 21, 21 a, 21 b, 21 c, 21 d, 21 e. The supports maygenerally space the bottom surface of the base from the ground and/orother surface. The supports may also be spaced from each other suchthat, for example, the base may be manipulated with a forklift and/orother moving machinery fitting into the spaces between the supports.

FIGS. 21 and 21 a illustrate a plurality of extensions or supports 904extending from the bottom surface 902 of the base 900. In someembodiments, the extensions or supports may have some angled walls andmay have outer walls on the periphery of the base substantiallyperpendicular to the bottom surface 902, as illustrated with extensionsor supports 904.

In some other embodiments, the extensions or supports may be have angledwalls and be spaced inward from the outer periphery of the base, such asthe extensions or supports 914, 924 and 934 of bases 910, 920 and 930,respectively, illustrated in FIGS. 21 b, 21 c, 21 d and 21 e.

The bottom surface of the base and/or the sides of the supports may alsoinclude ridges, ribs, reinforcements and/or other surface modifications,as shown in FIGS. 21 b, 21 c and 21 d, to which may, for example, aid inincreasing the strength and/or rigidity of the structure of the base,especially under load. It is also believed that the ability of thesupports and/or base to resist compressive loads is greatly enhanced ifeach of the side walls includes a plurality of generally longitudinallyextending ribs. FIGS. 21b and 21d illustrate an example of ridges orribs 913 interconnecting on the walls of the extensions or supports 914and the bottom surface 912. FIG. 21c illustrates an example of grooves923 on the bottom surface 922, with unconnected ridges or ribs on theextensions or supports 924. FIG. 21e illustrates an example of largerraised ribs 933 on the bottom surface 932 from which the extensions orsupports 934 extend. The cargo containers may also include a desiccantto control the humidity of the interior.

In another exemplary embodiment of the invention, the container 200 isformed from two halves, and each of the halves may or may not includethe top or the bottom components. The interfacing locking features onthe components may include any or all combinations of those describedabove. In one embodiment, the container 200 includes two identical ormirror images substantially L-shaped cross-sectional halves, such as thehalves 220′ illustrated in FIGS. 22 and 22 a, each having at least twowall components 220, each of the components having correspondinginterlocking features to be mated together to form a container havingfor example, a closed enclosure therein when mated with the top 210 andbottom 230 components, as shown in FIG. 22 b.

In another embodiment of the invention, the container 200 includes twoidentical or mirror images of substantially L-shaped cross-sectionalhalves, such as the halves 210′ and 230′ as illustrated in FIGS. 23 and23 a, each having at least two walls 220 and a top component 210 or abase 230, respectively, joined to halves, each of the components havingcorresponding interlocking features to be mated together to form acontainer having for example, a closed enclosure therein.

For a container formed from two identical, substantially L-shapedcross-sectional halves 220′, or walls, each half 220′ may be integrallyformed or joined from two of the wall sections 220, as discussed above,to interface with a top 210 and a base 230 component. The wall sectionsmay generally be identical or similar in shape and size, and thoughintegrally formed or joined together, each still kept its distinctplatform portion 228. The halves 220′ may further include all of thefeatures of the constituent wall sections 220, as above, except wherethe halves 220′ are integrally formed, the features that would normallyinterface the two constituent wall sections 220 may be absent and mayinstead form a solid continuous structure. In these embodiments, eachhalf 220′ includes two vertical edges, such as interfaces 224 and 226 b,and two horizontal edges, such as 226 a and 226 c, to interconnect withother components, for example, with each other and with the top 210 andbase 230 to form the container 200 with internal space 201, asillustrated in FIG. 22 b. The halves 220′ may, such as by virtue oftheir shape and by being identical, may nest together which maygenerally conserve space during storage in knocked down form.

In one embodiment, one substantially L-shaped cross-sectional half maybe integrally formed or joined with a top component, as shown with half210′ formed from wall sections 220 joined to the top 210 as illustratedin FIG. 23 a, while another substantially L-shaped cross-sectional halfmay be integrally formed or joined with a bottom or base component, asillustrated in FIG. 23 with half 230′ formed from wall sections 220joined to the base 230, such that the two halves 210′, 230′ may beassembled to form a complete enclosed container 200, as illustrated inFIG. 23 b. As with the halves 220′, the wall sections in the halves210′, 230′ may generally be identical or similar in shape and size, andthough integrally formed or joined together, each still kept itsdistinct platform portion 228. The halves 210′, 230′ may further includeall of the features of the constituent wall sections 220, as above,except where the halves 210′, 230′ are integrally formed, the featuresthat would normally interface the two constituent wall sections 220 andthe top 210 or base 230 may be absent and may instead form a solidcontinuous structure. In these embodiments, each half 210′, 230′includes two vertical edges, such as interfaces 224 and 226 b, and twohorizontal edges, such as 226 a and 226 c, to interconnect with othercomponents, for example, with each other, and the base 230 may include agroove 236 to interface with the edges of the half 210′ while the top210 may include a groove 216 to interface with the edges of the half230′ to form the container 200 with internal space 201, as illustratedin FIG. 23 b. The halves 210′, 230′ may, such as by virtue of theirshape and by being similar, may nest together with other halves of thesame type or the other type, which may generally conserve space duringstorage in knocked down form.

For the halves 210′, 220′, 230′ as described above, the edges may berounded or chamfered, as illustrated with, for example, the roundededges 223, or they may also be substantially 90 degree interfaces whichare not rounded or smoothed (not shown).

As noted above, the interfacing features may be formed during any stepof the manufacturing process. In one example, the features may be moldedwhen the components are made. The base, top or walls may include a lightweight core, for example, a closed cell foamed core, combined with orsurrounded by a polymeric film to form a strengthened structure. Thecore may include the interfacing features and the polymeric film maythen conform to the features in the core during the combining orsurrounding step or process. In another embodiment, the features may beforged into the components after the components are made. For example,the base, top or walls may include a light weight core, for example, aclosed cell foamed core, combined with or surrounded by a polymeric filmto form a strengthened structure. The core does not include any of theinterfacing features. The interfacing features may then be forged afterthe core and film are combined, and the exposed surface of the core mayeither remain exposed or a spray coating made be added to cover theexposed surface of the core.

In various embodiments of the invention, one or more of the dunnageplatform, the first enclosure and second enclosure are formed from acore, from one or more of the materials including expanded polystyrene,polyurethane, polyphenylene ether, polystyrene impregnated with pentane,a blend of polyphenylene ether and polystyrene impregnated with pentane,polyethylene, and polypropylene. In various embodiments of theinvention, one or more of the dunnage platform, the first enclosure andsecond enclosure are formed from a core containing one or more materialsmentioned above. In various embodiments of the invention, one or more ofthe dunnage platform, the first enclosure and second enclosure areformed from one or more thermoplastic sheets or layers including highimpact polystyrene; polyolefins such as polypropylene, low densitypolyethylene, high density polyethylene, polyethylene, polypropylene;polycarbonate; acrylonitrile butadiene styrene; polyacrylonitrile;polyphenylene ether; polyphony ether alloyed with high impactpolystyrene; polyester such as PET (polyethylene terephthalate), APET,and PETG; lead free PVC; copolymer polyester/polycarbonate; or acomposite HIPS structure, as mentioned above.

In various embodiments of the invention, one or more of the dunnageplatform, the first enclosure and second enclosure thermoplastic sheetsare a blend of any of the polymers mentioned above. In variousembodiments of the invention, one or more of the dunnage platform, thefirst enclosure and second enclosure are formed from a core with anembedded strengthening material selected from the group consisting of amesh, a perforated sheet and a barrier is embedded in the core. Invarious embodiments of the invention, one or more of the dunnageplatform, the first enclosure and second enclosure are formed from acore with an embedded strengthening material selected from the groupconsisting of metal, carbon fiber, Kevlar, basalt-web blanket andFormica. As noted above, when used in facilitating security check of aircargo transport of cargo that is transparent to magnetic scanners,non-metal containers may be used.

As noted above, the polymeric layer, for example, sheets or the coatingsthereon the polymeric layer, may include chemical anti-microbialmaterials or compounds that are capable of being substantiallypermanently bonded, at least for a period such as the useful life of theloading bearing structure or maintain their anti-microbial effects whencoated with the aid of processing aids or coating agents, onto theexposed surfaces of the polymeric layer, for example, sheet or coating67. In one example, the chemicals may be deposited on the surface of thepolymeric layer, for example, sheet or coating 67 or incorporated intothe material of the polymeric layer, for example, sheet or coating 67.Antimicrobial activity may be built into the surface 16 itself by, forexample, covalently bonding antimicrobial agents to the surface of thepolymeric layer, for example, sheet or coating 67, or if incorporatedinto the bulk of the material for making the polymeric layer, forexample, sheet or sprayed coating, may migrate to the surface. Thesecovalently bonded materials may act to minimize microbial growth on thesurface, either disposable or reusable. In addition, any microbialorganisms that may chance to be attached to the material may be killedby interaction with the coating. For example, quaternary ammoniumcations, such as N-alkyl-pyridiniums, may be used as antimicrobialmoieties in covalently attached polymeric surface coatings. In one case,poly(4-vinyl-N-hexylpyridinium) (N-alkylated-PVP) was previously notedto have an optimum alkyl side chain length for antimicrobial activity.Polyethylenimine (PEI) was also previously used as a bacteriocidalcoating when both N-alkylated on its primary amino group andsubsequently N-methylated on its secondary and tertiary amino groups toraise the overall number of cationic quaternary amino groups. Any suchcovalently bonded quaternary ammonium cation polymeric coatings may beused to give an antimicrobial property to the surface or surfaces of theloading bearing structures. Further examples of quaternary ammoniumcompounds include, but are not limited to, benzalkonium chloride,benzethonium chloride, methylbenzethonium chloride, cetalkoniumchloride, cetylpyridinium chloride, cetrimonium, cetrimide, dofaniumchloride, tetraethylammonium bromide, didecyldimethylammonium chlorideand domiphen bromide.

For bulk incorporation of the antimicrobial agent or agents into thematerial used in making the polymeric layer, for example, sheet orsprayed coating, the agent or agents maybe dispersed directly into thematerial, or with the aid of an appropriate carrier, for example, abinding agent, a solvent, or a suitable polymer mixing aid. Thesecarriers maybe chosen so that they are mixable with the material formaking the polymeric layer, for example, sheets or sprayed coatings andcompatible with the antimicrobial agent or agents used. Effectivebinding agents are those that do not interfere with the antimicrobialactivities of the antimicrobial agent.

As noted above, an additional enclosure, such as bag like enclosure maybe used to cover any of the load bearing structures described above. Thepresent invention also discloses a system designed to facilitate thesecurity checking process, including a light weight load bearingstructure for loading perishable or non-perishable cargo, the loadbearing structure having a top deck, a bottom deck and a width joiningthe top and the bottom, the bottom deck having a plurality of extensionsor supports extending therefrom and the cargo is loaded onto the topdeck of the load bearing structure; and a bag-like enclosure forcovering the cargo and at least a portion of the width of the loadbearing structure, with the bag-like enclosure having an opening with anelastic property about its circumference for stretching about the widthof the load bearing structure. The load bearing structure and bag-likeenclosure in this configuration are both transparent to magnetic imagingscanners used in security scanning to facilitate the security check ofperishable cargo or non-perishable cargo, large or small, without theneed for unloading and reloading of the cargo from the load bearingstructure.

The bag like enclosure may be made from a film, a woven sheet or anon-woven sheet having sufficient strength for stretching over andcovering a cargo and light weight enough not to add unnecessary weightto the cargo. It may be closed on three sides and opened at one end,with the open end having some elastic property circumferentially aboutthe opening. The cargo may be packed and the bag-like material stretchedover the entire cargo with the open end stretched under the edge of baseand tagged at the origin and the complete structure may beshrink-wrapped. The surfaces of the bag-like material may also haveanti-microbial properties. Any of the antimicrobial embodimentsdescribed above may be suitable. More details are found in U.S. patentapplication Ser. No. 13/549,477, entitled “SYSTEM FOR FACILITATINGSECURITY CHECK OF SHIPMENT OF CARGO”, the content of which is herebyincorporated by reference in its entirety.

While the invention has been particularly shown and described withreference to exemplary embodiments, it should be understood by thoseskilled in the art that changes in form and detail may be made thereinwithout departing from the spirit and scope of the invention.

1. A loading bearing structure comprising: an expanded polymer corehaving a top side, a bottom side and a width having a thicknesstherebetween joining the top side and the bottom side; and at least onepolymer sheet having a first side with outer edge portions, said firstside of said polymeric sheet including the outer edge portions arecombined with said bottom side, the width and at least a portion of saidtop side of said expanded polymeric core; wherein said outer edgeportions of said first side of the polymeric sheet is sealed to portionsof the expanded polymeric core by at least one sealing feature, saidsealing feature is present at the peripheral of the outer edges of thepolymeric sheet only for minimizing imperfections in the combining ofthe polymeric sheet with the core at the outer edges.
 2. The loadbearing structure of claim 1, wherein said at least one sealing featurecomprise a sealing liquid, a sealing chemical composition, aself-healing composition, a sealing tape, a mechanical and/or heatsealing device or combinations thereof.
 3. The loading bearing structureof claim 2, wherein said sealing tape comprises two surfaces having aheat activatable adhesive on one surface and a tacky adhesive on thesecond surface.
 4. The loading bearing structure of claim 2, whereinsaid self healing composition comprises polyurethane-chitosan blendedpolymers, polymers of condensation reaction products of paraformaldehydeand 4,4′-oxydianiline or combinations thereof.
 5. The loading bearingstructure of claim 2, wherein said self healing composition comprisespolymers which repolymerize with themselves when exposed to ultravioletlight and/or other electromagnetic radiation and/or heat.
 6. The loadingbearing structure of claim 1, wherein said at least one sealing featurecomprises a moderate to good solvent of said core and/or said polymericsheet.
 7. The loading bearing structure of claim 2, wherein said atleast one sealing liquid comprises tetrachloroethylene.
 8. The loadingbearing structure of claim 1, further comprising at least one edgeprotector positioned about a portion of the bottom side and a portion ofthe width close to the bottom side of the load bearing structure foraccommodating at least one cargo-holding feature.
 9. A loading bearingstructure having a top side, a bottom side and a width therebetween,comprising: an expanded polymer core with a top side, a bottom side anda width having a thickness therebetween joining the top side and thebottom side; a first polymer sheet having a first side and a secondside, with outer edges, said first side and its outer edges are combinedwith said bottom side and at least part of said thickness of said widthof said expanded polymer core; and a second polymer sheet having a firstside and a second side, with outer edges, said second side and its outeredges are combined with said expanded polymer core on said top side andat least part of the thickness of the width of said expanded polymercore, forming an overlap between said outer edges of said first sheetand said outer edges of said second sheet about the width, said overlaphaving an outer edge; wherein only the peripheral of said overlappedouter edges between the first and second the polymeric sheets are sealedby at least one sealing feature for minimizing imperfections in thecombining of the polymeric sheet with the core at the outer edges of theoverlapped area.
 10. The load bearing structure of claim 9, wherein saidat least one sealing feature comprises a sealing liquid, a sealingchemical composition, a sealing tape, a self-healing composition, amechanical and/or heat sealing device or combinations thereof.
 11. Theloading bearing structure of claim 10, wherein said sealing tapecomprises two surfaces having a heat activatable adhesive on one surfaceand a tacky adhesive on the second surface.
 12. The loading bearingstructure of claim 9, wherein said at least one sealing featurecomprises a moderate to good solvent of said polymeric sheets.
 13. Theloading bearing structure of claim 10, wherein said at least one sealingliquid comprises tetrachloroethylene.
 14. The load bearing structure ofany of claim 9, further comprising at least one edge protectorpositioned about the bottom edge and a portion of the width close to thebottom edge of the load bearing structure for accommodating at least onecargo-holding feature.
 15. The loading bearing structure of claim 7,wherein said loading bearing structure having anti-microbial propertiesadapted for receiving cargo generated in a clean room to facilitateshipping and minimizing risk of contamination or damage.
 16. A loadingbearing structure comprising: an expanded polymer core having a topside, a bottom side and a width having a thickness therebetween joiningthe top side and the bottom side; and at least one polymer sheet havinga first side with outer edge portions, said first side of said polymericsheet including the outer edge portions are combined with said bottomside, the width and at least a portion of said top side of said expandedcore, creating an interface between said polymer sheet and said expandedpolymer core; wherein the interface at the outer edges of said firstside of the polymeric sheet and said expanded polymer core includes atleast one sealing feature, said sealing feature is present at theperipheral of the outer edges of the polymeric sheet only for minimizingadhesive or cohesive failure at the interface.
 17. The load bearingstructure of claim 16, further comprising at least one edge protectorpositioned about a portion of the bottom side and a portion of the widthclose to the bottom side of the load bearing structure for accommodatingat least one cargo-holding feature to aid in holding the cargo in placeto minimize movement.
 18. The load bearing structure of claim 16,wherein said edge protectors are positioned continuously orintermittently around the loading bearing structure.
 19. The loadbearing structure of claim 16, further comprising a second polymer sheethaving a first side and a second side, with outer edges, said secondside and its outer edges are combined with said expanded polymer core onsaid top side and at least part of the thickness of the width of saidexpanded polymer core.
 20. The load bearing structure of claim 17,wherein said edge protector is flushed with the rest of the structure.